Functional food supplements to ameliorate the secondary complications in high fructose fed diabetic rats.

Functional foods are the most natural and safest source of health ingredients, providing health benefits beyond basic nutrition, and hence can be used as supplements for the prevention of secondary complications in diabetes. Persistent diabetes may cause glycation of various tissue proteins such as of those in lens, kidney, blood, and brain, which may further lead to the development of pathological conditions such as cataract and cardiovascular diseases. This study on adult rats was designed to assess if the functional food supplements A and B (proprietary blends of antioxidant rich plant materials) can reduce secondary complications such as cataract, dyslipidemia, and oxidative stress under severe diabetic conditions. After nine weeks of intervention of the supplements, it was found that the % HbA1c levels in the formulation group B significantly (p < 0.05) lowered (10.9%) followed by those in group A (11.1%) as compared to those in the diabetic fructose control (DFC) group (15.1%); moreover, plasma insulin levels were significantly (p < 0.01) improved in the formulation B group (9.8 mU L-1) as compared to those in the DFC group (8.5 mU L-1). The significantly higher level of plasma TEAC in group B (27.5 mg dL-1) (p < 0.02) and group A (26.6 mg dL-1) (p < 0.05) indicates an improved plasma antioxidants status as compared to that in DFC group (21.7 mg dL-1). Both the formulation groups A and B showed a decrease in AGEs and tryptophan fluorescence, which suggests amelioration of the glycation of lens proteins as compared to that in the DFC group. The present results indicate that the formulations A and B exhibit antiglycating and antioxidant potentials by inhibiting the high fructose-induced glycation in diabetic rats; hence, they may have therapeutic value as functional foods in the effective management of secondary complications associated with severe diabetic conditions.

tRNA-mediated protein engineering.

Novel methods of incorporating non-native amino acids and stable isotope labels into proteins using modified tRNAs present new opportunities for basic research and biotechnology that go beyond conventional site-directed mutagenesis. tRNA-mediated protein engineering relies on the development of novel tRNAs and their misacylation with custom-designed amino acids, the recognition of special codons by the tRNAs, and the efficient expression of these modified proteins. Recent progress has been made in all these areas, including the development of more effective suppresor tRNAs and higher yield translation systems, leading to a variety of novel applications.

Preparation and properties of RNase T1 immobilized on aminoethyl Bio-Gel P-2.

The partially purified RNase T1, when coupled to glutaraldehyde activated aminoethyl Bio-Gel P-2, retained 22-24% activity of the soluble enzyme. Immobilization resulted in an increase in the optimum temperature and temperature stability, but it did not affect the pH optimum. Km and Vmax decreased as a result of immobilization. The bound enzyme showed high stability to repeated use and storage.

Characterization of S1 nuclease. Involvement of carboxylate groups in metal binding.

Modification of the carboxylate groups of purified S1 nuclease resulted in a loss of its single-stranded DNAase, RNAase and phosphomonoesterase activities. The inactivation was due to the removal of zinc atoms from the enzyme and this in turn was dependent on the degree of modification. While the removal of one zinc atom resulted in the partial inactivation of the enzyme, removal of the remaining zinc atoms resulted in the complete inactivation of the enzyme. Similar results were obtained when the purified enzyme was incubated with various concentrations of the metal chelator, EDTA. The EDTA-(1 mM)-treated enzyme, depleted of one zinc atom, showing 40-45% residual activity, when incubated with 1 mM Zn2+ or 1 mM Co2+, regained a significant amount of its initial activity towards all the substrates. However, Woodward's-Reagent-K-modified enzyme depleted of one zinc atom and having the same level of activity (40-45%) could not regain its activity, indicating that the carboxylate groups are involved in the metal binding. Data obtained with carboxylate-group modification, EDTA-treatment, reconstitution with metal ions, zinc estimation and CD analysis of the enzyme suggests that, out of three zinc atoms present in S1 nuclease, zinc I is easily replaceable and is probably involved in the catalytic activity while zinc II and zinc III are involved in maintaining the enzyme structure.

Preparation, properties and application of Aspergillus oryzae S1 nuclease covalently bound to aminobutyl-Bio-Gel P-2 through its carbohydrate moiety.

Purified Aspergillus oryzae S1 nuclease, when covalently coupled to aminobutyl-(AB)-Bio-Gel P-2, via its carbohydrate moiety, retained 40-50% activity of the soluble enzyme. Optimization of coupling conditions showed that the most active immobilized preparations are obtained when 50-60 units of 1 mM periodate-oxidized enzyme are allowed to react with 1 ml (packed volume) of AB-Bio-Gel P-2 at 4 degrees C, in the presence of 20% (v/v) ethylene glycol, for 15 h. Immobilization did not change the pH and temperature optima of the enzyme, but it increased the temperature-stability. Immobilization brought about an approx. 2-fold increase in the Km and a slight decrease in the Vmax. On repeated use, the bound enzyme retained 60-65% of its initial activity after six cycles. Immobilized S1 nuclease could be stored, in a wet state, for more than 45 days without any significant loss in its initial activity. The application of AB-Bio-Gel- and concanavalin A-Sepharose-bound S1 nuclease in removing restriction-endonuclease-generated single-stranded tails in plasmid DNA is demonstrated.

S1 nuclease: immunoaffinity purification and evidence for the proximity of cysteine 25 to the substrate binding site.

A simple procedure, involving heat treatment, gel filtration on Sephadex-G 100 followed by chromatography on anti-S1 nuclease antibodies bound to Sepharose, was developed for purification of S1 nuclease to homogeneity with an overall yield of 72%. S1 nuclease was rapidly inactivated, at pH 6.0 and 37 degrees C, in presence of o-phthalaldehyde. Kinetic analysis of o-phthalaldehyde medicated inactivation showed that the reaction followed pseudo-first-order kinetics and the loss of enzyme activity was due to the formation of a single isoindole derivative per molecule of the enzyme. Absorbance and fluorescence spectrophotometric data also gave similar results. The isoindole derivative formation, as a result of o-phthalaldehyde treatment is known to occur through crosslinking of the thiol group of cysteine and the epsilon-amino group of lysine, situated in close proximity in the native enzyme. Since, modification of the only available cysteine residue (Cys25) did not affect the catalytic activity of the enzyme, the o-phthalaldehyde mediated inactivation of S1 nuclease is due to the modification of lysine. Substrates of S1 nuclease, namely ssDNA, RNA, 3'AMP, could protect the enzyme against o-phthalaldehyde mediated inactivation. Moreover, the modified enzyme (having very little catalytic activity) showed a significant decrease in its ability to bind 5'AMP, a competitive inhibitor of S1 nuclease, suggesting that the modification has occurred at the substrate binding site. The above results point towards the presence of cysteine 25 in close proximity to the substrate binding site.

Active-site characterization of S1 nuclease. II. Involvement of histidine in catalysis.

Modification of the histidine residues of purified S1 nuclease resulted in loss of its single-stranded (ss)DNAase, RNAase and phosphomonoesterase activities. Kinetics of inactivation indicated the involvement of a single histidine residue in the catalytic activity of the enzyme. Furthermore, histidine modification was accompanied by the concomitant loss of all the activities of the enzyme, indicating the presence of a common catalytic site responsible for the hydrolysis of ssDNA, RNA and 3'-AMP. Substrate protection was not observed against Methylene Blue- and diethyl pyrocarbonate (DEP)-mediated inactivation. The histidine (DEP)-modified enzyme could effectively bind 5'-AMP, a competitive inhibitor of S1 nuclease, whereas the lysine (2,4,6-trinitrobenzenesulphonic acid)-modified enzyme showed a significant decrease in its ability to bind 5'-AMP. The inability of the substrates to protect the enzyme against DEP-mediated inactivation, coupled with the ability of the modified enzyme to bind 5'-AMP effectively, suggests the involvement of histidine in catalysis.

Single-strand-specific nucleases.

Single-strand-specific nucleases, which act on single-stranded nucleic acids and single-stranded regions in double-stranded nucleic acids, are multifunctional enzymes and are ubiquitous in distribution. They find wide application as analytical tools in molecular biology research, although enzymes such as P1 nuclease are also used for production of flavor enhancers such as 5' IMP and 5' GMP. Because these enzymes are mainly used as analytical tools, very little attention was paid to aspects relating to their structure-function relationships. However, during the last few years considerable developments have taken place in this area. Single-strand-specific nucleases, their purification, characteristics, biological role, and applications have been reviewed.

Partial purification and immobilization of ribonuclease T2.

A simple procedure, consisting of water extraction, heat treatment at pH 2.0, negative adsorption on DEAE-cellulose at pH 4.9, and concanavalin A-Sepharose chromatography, was developed for the partial purification of ribonuclease (RNase) T2 from taka-diastase powder with an overall yield of 5.5%. The partially purified enzyme when coupled to aminoethyl Bio-Gel P-60, retained 12-16% of the activity of the soluble enzyme. Temperature stability studies on RNase T2 bound to matrices, activated with increasing concentrations of glutaraldehyde, and the influence of lysine modification on the activity of the soluble enzyme revealed that the low activity observed for the gel-bound enzyme is probably due to the masking of the active site of the enzyme as a result of the involvement of lysine residues, situated near the active site, during coupling. Immobilization did not affect the pH and temperature optima of RNase T2. On repeated use, the bound enzyme retained approximately 55% of its initial activity after six cycles. These results are discussed, taking into consideration the factors affecting immobilized enzymes.

Active-site characterization of S1 nuclease. I. Affinity purification and influence of amino-group modification.

A simple procedure, involving heat-treatment, DEAE-Sephadex, AMP-Sepharose and Bio-Gel P-60 chromatography, was developed for the purification of S1 nuclease to homogeneity from commercially available Takadiastase powder. Chemical modification of the amino groups of purified S1 nuclease revealed that lysine is essential for single-stranded DNAase, RNAase and phosphomonoesterase activities associated with the enzyme. The kinetics of inactivation suggested the involvement of a single lysine residue in the active site of the enzyme. Additionally, lysine modification was accompanied by a concomitant loss of all the activities of the enzyme, indicating the presence of a common catalytic site responsible for the hydrolysis of single-stranded DNA, RNA and 3'-AMP. Substrate-protection and inhibitor-binding studies on enzyme modified with 2,4,6-trinitrobenzenesulphonic acid showed that lysine may be involved in the substrate binding.

Lysine 207 as the site of cross-linking between the 3'-end of Escherichia coli initiator tRNA and methionyl-tRNA formyltransferase.

The specific formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for initiation of protein synthesis in Escherichia coli. In attempts to identify regions of MTF that come close to the 3'-end of the tRNA, we oxidized 32P-3'-end-labeled E. coli initiator methionine tRNA with sodium metaperiodate and cross-linked it to MTF. The cross-linked MTF was separated from uncross-linked MTF by DEAE-cellulose chromatography, and the tRNA in the cross-linked MTF was hydrolyzed with nuclease P1 and RNase T1, leaving behind an oxidized fragment of [32P]AMP attached to MTF. Trypsin digestion of the cross-linked MTF followed by high pressure liquid chromatography of the digest yielded two peaks of radioactive peptides, I* and II*. These peptides were characterized by N- and/or C-terminal sequencing and by matrix-assisted laser desorption ionization mass spectroscopy. Peptide I* contained amino acids Gln186-Lys210 with Lys207 as the site of the cross-link. Peptide II*, a partial digestion product, contained amino acids Gln186-Arg214 also with Lys207 as the site of the cross-link. The molecular masses of peptides I* and II* indicate that the final product of the cross-linking reaction between the periodate-oxidized AMP moiety of the tRNA and Lys207 is most likely a morpholino derivative rather than a reduced Schiff's base.

Affinity Labeling of the active site of rabbit muscle adenylosuccinate lyase by 2-[(4-bromo-2.3-dioxobutyl)thio] adenosine 5'-monophosphate.

Rabbit muscle adenylosuccinate lyase upon incubation with 7.5-50 muM 2 -[(4-bromo-2.3-dioxobutyl)thio]adenosine 5'-monophosphate (2-BDB-TAMP) in 0.05 M PIPES buffer, ph 7.0 and 10 degrees C, gives a time dependent biphasic inactivation. The rate of inactivation exhibits a nonlinear dependence on the concentration 2-BDB-TAMP, which can be described by reversible binding of reagent to the enzyme (K1=8.5 microM. 5.2 microM) prior to the irreversible reaction, with maximum rate constants of 0.319 and 0.027 min-1 for the fast and slow phases, respectively. The enzyme is a tetramer, with subunits of 50 000 Da. When the enzyme was 90% inactivated, 0.84 mol of reagent/mol of subunit was incorporated as measured by protein-bound phosphate analysis; similar results were obtained using 2-BDB-[14C]TAMP. Complete protection against inactivation and incorporation was afforded by 1 mM 5'-AMP and by 0.1 mM 5'-AMP + 5 mM fumarate (the natural products of adenylosuccinate hydrolysis) but not by 0.1 mM 5'-AMP alone, 5 mM fumarate alone, or 0.1 mM 5'-AMP + 5 mM maleate or 5 mM succinate. These studies suggest that 2-BDB-TAMP inactivates adenylosuccinate lyase by specific reaction at the substrate binding site, with negative cooperativity between subunits accounting for the appearance of two phases of inactivation. Cleavage of 2-BDB-TAMP-modified enzyme with cyanogen bromide and subsequent separation of peptides by reverse phase HPLC gave only one radioactive peak. This radioactive peptide was further digested with papain and the target site of the 2-BDB-TAMP reaction was identified as Arg112. We conclude that Arg112 is located in the substrate binding site of rabbit muscle adenylosuccinate lyase.

Escherichia coli methionyl-tRNA formyltransferase: role of amino acids conserved in the linker region and in the C-terminal domain on the specific recognition of the initiator tRNA.

The formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in eubacteria. We are studying the molecular mechanisms of recognition of the initiator tRNA by Escherichia coli MTF. MTF from eubacteria contains an approximately 100-amino acid C-terminal extension that is not found in the E. coli glycinamide ribonucleotide formyltransferase, which, like MTF, use N(10)-formyltetrahydrofolate as a formyl group donor. This C-terminal extension, which forms a distinct structural domain, is attached to the N-terminal domain through a linker region. Here, we describe the effect of (i) substitution mutations on some nineteen basic, aromatic and other conserved amino acids in the linker region and in the C-terminal domain of MTF and (ii) deletion mutations from the C-terminus on enzyme activity. We show that the positive charge on two of the lysine residues in the linker region leading to the C-terminal domain are important for enzyme activity. Mutation of some of the basic amino acids in the C-terminal domain to alanine has mostly small effects on the kinetic parameters, whereas mutation to glutamic acid has large effects. However, the deletion of 18, 20, or 80 amino acids from the C-terminus has very large effects on enzyme activity. Overall, our results support the notion that the basic amino acid residues in the C-terminal domain provide a positively charged channel that is used for the nonspecific binding of tRNA, whereas some of the amino acids in the linker region play an important role in activity of MTF.

Ultrasensitive fluorescence-based detection of nascent proteins in gels.

The most common method of analysis of proteins synthesized in a cell-free translation system (e.g., nascent proteins) involves the use of radioactive amino acids such as [(35)S]methionine or [(14)C]leucine. We report a sensitive, nonisotopic, fluorescence-based method for the detection of nascent proteins directly in polyacrylamide gels. A fluorescent reporter group is incorporated at the N-terminus of nascent proteins using an Escherichia coli initiator tRNA(fmet) misaminoacylated with methionine modified at the alpha-amino group. In addition to the normal formyl group, we find that the protein translational machinery accepts BODIPY-FL, a relatively small fluorophore with a high fluorescent quantum yield, as an N-terminal modification. Under the optimal conditions, fluorescent bands from nanogram levels of in vitro-produced proteins could be detected directly in gels using a conventional UV-transilluminator. Higher sensitivity ( approximately 100-fold) could be obtained using a laser-based fluorescent gel scanner. The major advantages of this approach include elimination of radioactivity and the rapid detection of the protein bands immediately after electrophoresis without any downstream processing. The ability to rapidly synthesize nascent proteins containing an N-terminal tag facilitates many biotechnological applications including functional analysis of gene products, drug discovery, and mutation screening.

Suppressor mutations in Escherichia coli methionyl-tRNA formyltransferase: role of a 16-amino acid insertion module in initiator tRNA recognition.

The specific formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF; EC 2.1.2.9) is important for the initiation of protein synthesis in eubacteria and in eukaryotic organelles. The determinants for formylation in the tRNA are clustered mostly in the acceptor stem. As part of studies on the molecular mechanism of recognition of the initiator tRNA by MTF, we report here on the isolation and characterization of suppressor mutations in Escherichia coli MTF, which compensate for the formylation defect of a mutant initiator tRNA, lacking a critical determinant in the acceptor stem. We show that the suppressor mutant in MTF has a glycine-41 to arginine change within a 16-amino acid insertion found in MTF from many sources. A mutant with glycine-41 changed to lysine also acts as a suppressor, whereas mutants with changes to aspartic acid, glutamine, and leucine do not. The kinetic parameters of the purified wild-type and mutant Arg-41 and Lys-41 enzymes, determined by using the wild-type and mutant tRNAs as substrates, show that the Arg-41 and Lys-41 mutant enzymes compensate specifically for the strong negative effect of the acceptor stem mutation on formylation. These and other considerations suggest that the 16-amino acid insertion in MTF plays an important role in the specific recognition of the determinants for formylation in the acceptor stem of the initiator tRNA.

Functional interaction of an arginine conserved in the sixteen amino acid insertion module of Escherichia coli methionyl-tRNA formyltransferase with determinants for formylation in the initiator tRNA.

Formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for initiation of protein synthesis in eubacteria. The determinants for formylation are clustered mostly in the acceptor stem of the initiator tRNA. Previous studies suggested that a 16 amino acid insertion loop, present in all eubacterial MTF's (residues 34-49 in the E. coli enzyme), plays an important role in specific recognition of the initiator tRNA. Here, we have analyzed the effect of site-specific mutations of amino acids within this region. We show that an invariant arginine at position 42 within the loop plays a very important role both in the steps of substrate binding and in catalysis. The kinetic parameters of the R42K and R42L mutant enzymes using acceptor stem mutant initiator tRNAs as substrates suggest that arginine 42 makes functional contacts with the determinants at the 3:70 and possibly also the 2:71 base pairs in the acceptor stem of the initiator tRNA. The kinetic parameters of the G41R/R42L double mutant enzyme are essentially the same as those of R42L mutant, suggesting that the requirement for arginine at position 42 cannot be fulfilled by an arginine at position 41. Along with other data, this result suggests that the insertion loop, which is normally unstructured and flexible, adopts a defined conformation upon binding to the tRNA.

Induced fit of a peptide loop of methionyl-tRNA formyltransferase triggered by the initiator tRNA substrate.

A 16-aa insertion loop present in eubacterial methionyl-tRNA formyltransferases (MTF) is critical for specific recognition of the initiator tRNA in Escherichia coli. We have studied the interactions between this region of the E. coli enzyme and initiator methionyl-tRNA (Met-tRNA) by using two complementary protection experiments: protection of MTF against proteolytic cleavage by tRNA and protection of tRNA against nucleolytic cleavage by MTF. The insertion loop in MTF is uniquely sensitive to cleavage by trypsin. We show that the substrate initiator Met-tRNA protects MTF against trypsin cleavage, whereas a formylation-defective mutant initiator Met-tRNA, which binds to MTF with approximately the same affinity, does not. Also, mutants of MTF within the insertion loop (which are defective in formylation) are not protected by the initiator Met-tRNA. Thus, a functional enzyme-substrate complex is necessary for protection of MTF against trypsin cleavage. Along with other data, these results strongly suggest that a segment of the insertion loop, which is exposed and unstructured in MTF, undergoes an induced fit in the functional MTF.Met-tRNA complex but not in the nonfunctional one. Footprinting experiments show that MTF specifically protects the acceptor stem and the 3'-end region of the initiator Met-tRNA against cleavage by double and single strand-specific nucleases. This protection also depends on formation of a functional MTF.Met-tRNA complex. Thus, the insertion loop interacts mostly with the acceptor stem of the initiator Met-tRNA, which contains the critical determinants for formylation.