Purification and characterization of SDG-β-d-glucosidase hydrolyzing secoisolariciresinol diglucoside to secoisolariciresinol from Aspergillus oryzae

The SDG-β-d-glucosidase that hydrolyzes the glucopyranoside bond of secoisolariciresinol diglucoside (SDG) to release secoisolariciresinol (SECO) was isolated from Aspergillus oryzae 39 strain and the enzyme was purified and characterized. The enzyme was purified to one spot in SDS polyacrylamide gel electrophoresis, and its molecular weight was about 64.9 kDa. The optimum temperature of the SDG-β-d-glucosidase was 40 °C, and the optimum pH was 5.0. The SDG-β-d-glucosidase was stable at less than 65 °C, and pH 4.0–6.0. Ca²⁺, K⁺, Mg²⁺ and Na⁺ ions have no significant effect on enzyme activity, Zn²⁺ and Cu²⁺ ions have weakly effect on enzyme activity, but Fe³⁺ ion inhibits enzyme activity strongly. The K_m value of SDG-β-d-glucosidase was 0.14 mM for SDG.     

Biological activities of lignans and neolignans on the aphid Myzus persicae (Sulzer)

Lignans and neolignans have been reported to exert different biological activities, including insecticidal ones. Three lignans, secoisolariciresinol (SECO), secoisolariciresinol diglucoside (SDG), and anhydrosecoisolariciresinol (AHS), and one neolignan, dehydrodiconiferyl alcohol-4-β-d-glucoside (DCG), were isolated from flax. Their insecticidal properties were evaluated on the aphid Myzus persicae reared on artificial diet. Life history parameters, i.e., nymphal survival, prereproductive period, and daily fecundity, were assessed and used to calculate the intrinsic rate of natural increase and the doubling time of aphid populations. Compared to the control, SDG and DCG significantly increased aphid mortality by at least 25 %, while SECO and AHS did not affect their survival. SDG did not affect life history parameters, except at the highest concentration of 100 μg/mL, which increased the population’s doubling time by more than 5 days. DCG altered all the life history parameters at all concentrations assayed. SECO induced significant deleterious effects on the aphids, except at the highest concentration of 100 μg/mL. AHS only altered prereproductive period, which increased by at least 2 days at 50 and 100 μg/mL. Lignans and neolignans are potential new bioinsecticides against aphids in the context of alternative management programs.     

The amino acid sequence of human APOA-I, an apolipoprotein isolated from high density lipoproteins.

The complete amino acid sequence of human A-I has been determined by manual and automated Edman degradation of intact and peptide fragments of A-I. A-I is a single chain protein of 243 residues with the following amino acid composition: Asp₁₆, Asn₅, Thr₁₀, Ser₁₅, Glu₂₇, Gln₁₉, Pro₁₀, Gly₁₀, Ala₁₉, Val₁₃, Met₃, Leu₃₇, Tyr₇, Phe₆, Trp₄, Lys₂₁, His₅, and Arg₁₆. The amino acid sequence contains no linear segments of hydrophobic or hydrophilic residues. A detailed correlation of the amino acid sequence, conformation, and self association of A-I will add further insight into the molecular mechanisms involved in protein-protein and protein-lipid interactions.     

Syntheses and biological evaluation of analogs of luteinizing hormone-releasing hormone (LH-RH) modified in position 2, 3, 4 or 5

Syntheses by the conventional methods as well as the chemical, physical and biological properties are described of the following analogs of the LH-releasing hormone (LH-RH): [Leu³]-LH-RH, [Phe³]-LH-RH, [Trp²] [His³]-LH-RH, Des-Trp³-LH-RH, Des-His²-[Phe⁵]-LH-RH, [Ala⁴]-LH-RH, [Phe⁵]-LH-RH and [Ala⁴] [Phe⁵]-LH-RH. $\text{In vivo}$ assays showed that [Leu³]-LH-RH did not release LH in doses as high as 5 – 25 μg, having less than 0.0008% of LH-RH activity, while [Phe³]-LH-RH had 0.43% of the LH-RH activity of natural LH-RH. The LH-RH activities of [Trp²] [His³]-LH-RH, Des-Trp³-LH-RH and Des-His²-[Phe⁵]-LH-RH were extremely low. On the other hand, [Ala⁴]-LH-RH, [Phe⁵]-LH-RH and [Ala⁴] [Phe⁵]-LH-RH had significant LH-RH activity. The structure-activity relationship of LH-RH is discussed on the basis of these findings.     

Cloning,expression, and characterization of the β-glucosidase hydrolyzing secoisolariciresinol diglucoside to secoisolariciresinol from Bacteroides uniformis ZL1

Previously, from the human intestinal flora we isolated the bacterial strain Bacteroides uniformis ZL1, which could convert secoisolariciresinol diglucoside (SDG) to its aglycone secoisolariciresinol (SECO) in vivo. In this study, 24 putative β-glucosidase genes were screened from the genome of B. uniformis ATCC 8492, which were used as templates to design PCR primers for the target genes in B. uniformis ZL1. Fifteen genes (bgl1–bgl15) were amplified from strain ZL1, and among them we identified bgl8 as the gene encoding the SDG-hydrolyzing β-glucosidase. We sequenced the bgl8 gene, cloned it into the expression vector and then transformed Escherichia coli to construct the recombinant bacteria that could synthesize the target β-glucosidase (BuBGL8). We purified and characterized BuBGL8, which showed maximal activity and stability under the culture conditions of pH 6.0 and 30 °C. SDG (2.0 mg/ml) was converted to SECO by both the purified BuBGL8 (0.035 mg/ml) and crude enzyme extract (0.23 mg crude protein/ml) with the efficiency of more than 90 % after 90 min at the reaction conditions. This is, to our knowledge, the first report of using recombinant bacteria to synthesize the SDG-hydrolyzing β-glucosidase, which could be used to produce SECO from SDG conveniently and highly efficiently.     

A specific N-terminal extension of the 8 kDa domain is required for DNA end-bridging by human Polμ and Polλ

Human DNA polymerases mu (Polµ) and lambda (Polλ) are X family members involved in the repair of double-strand breaks in DNA during non-homologous end joining. Crucial abilities of these enzymes include bridging of the two 3′ single-stranded overhangs and trans-polymerization using one 3′ end as primer and the other as template, to minimize sequence loss. In this context, we have studied the importance of a previously uncharacterised sequence (‘brooch’), located at the N-terminal boundary of the Polß-like polymerase core, and formed by Tyr¹⁴¹, Ala¹⁴², Cys¹⁴³, Gln¹⁴⁴ and Arg¹⁴⁵ in Polµ, and by Trp²³⁹, Val²⁴⁰, Cys²⁴¹, Ala²⁴² and Gln²⁴³ in Polλ. The brooch is potentially implicated in the maintenance of a closed conformation throughout the catalytic cycle, and our studies indicate that it could be a target of Cdk phosphorylation in Polµ. The brooch is irrelevant for 1 nt gap filling, but of specific importance during end joining: single mutations in the conserved residues reduced the formation of two ended synapses and strongly diminished the ability of Polµ and polymerase lambda to perform non-homologous end joining reactions in vitro.     

Structure-function studies on gastrointestinal hormones: I. Synthesis of secretin analogs and their biological and immunological properties

Syntheses by conventional procedures of the three analogs corresponding to the porcine secretin sequence crossed at position 6 by the N-terminal hexapeptide sequences of VIP, GIP, and glucagon are described, viz., Ala⁴,Val⁵-, Tyr¹,Ala²,Glu³-, and Gln³-secretin (VIP-SN, GIP-SN, and GLU-SN). The analog Phe¹,Phe²,Trp³,Lys⁴-secretin (SOMA-SN), designed on the basis of the surprising homology of the sequence portions 10–13 of somatostatin and 5–8 of secretin, was also prepared. Finally, the synthesis of N^α-3-(4-hydroxyphenyl)propionyl-β-alanyl-secretin (DATA-SN), a tracer suitable for secretin radioimmunoassay and as an N-terminus modified secretin analog, is reported. The analogs are compared, in terms of their biological and immunological properties in different assay systems, with pure synthetic secretin.     

Increased tRNA level in yeast cells with mutant translation termination factors eRF1 and eRF3

We have earlier characterized Saccharomyces cerevisiae strains with mutations of essential SUP45 and SUP35, which code for translation termination factors eRF1 and eRF3, respectively. In this work, the sup45 and sup35 nonsense mutants were compared with respect to the levels of eight tRNAs: tRNA^Tyr, tRNA^Gln, tRNA^Trp, tRNA^Leu, tRNA^Arg (described as potential suppressor tRNAs), tRNA^Pro, tRNA^His, and tRNA^Gly. The mutants did not display a selective increase in tRNAs, capable of a noncanonical read-through at stop codons. Most of the mutations increased the level of all tRNAs under study. The mechanisms providing for the viability of the sup45 and sup35 nonsense mutants are discussed.     

Functional Characterization of ECP-Heparin Interaction: A Novel Molecular Model

Human eosinophil cationic protein (ECP) and eosinophil derived neurotoxin (EDN) are two ribonuclease A (RNaseA) family members secreted by activated eosinophils. They share conserved catalytic triad and similar three dimensional structures. ECP and EDN are heparin binding proteins with diverse biological functions. We predicted a novel molecular model for ECP binding of heparin hexasaccharide (Hep6), [GlcNS(6S)-IdoA(2S)]₃, and residues Gln⁴⁰, His⁶⁴ and Arg¹⁰⁵ were indicated as major contributions for the interaction. Interestingly, Gln⁴⁰ and His⁶⁴ on ECP formed a clamp-like structure to stabilize Hep6 in our model, which was not observed in the corresponding residues on EDN. To validate our prediction, mutant ECPs including ECP Q40A, H64A, R105A, and double mutant ECP Q40A/H64A were generated, and their binding affinity for heparins were measured by isothermal titration calorimetry (ITC). Weaker binding of ECP Q40A/H64A of all heparin variants suggested that Gln⁴⁰-His⁶⁴ clamp contributed to ECP-heparin interaction significantly. Our in silico and in vitro data together demonstrate that ECP uses not only major heparin binding region but also use other surrounding residues to interact with heparin. Such correlation in sequence, structure, and function is a unique feature of only higher primate ECP, but not EDN.     

Crystal Structure of Histamine Dehydrogenase from Nocardioides simplex

Histamine dehydrogenase (HADH) isolated from Nocardioides simplex catalyzes the oxidative deamination of histamine to imidazole acetaldehyde. HADH is highly specific for histamine, and we are interested in understanding the recognition mode of histamine in its active site. We describe the first crystal structure of a recombinant form of HADH (HADH) to 2.7-Å resolution. HADH is a homodimer, where each 76-kDa subunit contains an iron-sulfur cluster ([4Fe-4S]²⁺) and a 6-S-cysteinyl flavin mononucleotide (6-S-Cys-FMN) as redox cofactors. The overall structure of HADH is very similar to that of trimethylamine dehydrogenase (TMADH) from Methylotrophus methylophilus (bacterium W3A1). However, some distinct differences between the structure of HADH and TMADH have been found. Tyr⁶⁰, Trp²⁶⁴, and Trp³⁵⁵ provide the framework for the “aromatic bowl” that serves as a trimethylamine-binding site in TMADH is comprised of Gln⁶⁵, Trp²⁶⁷, and Asp³⁵⁸, respectively, in HADH. The surface Tyr⁴⁴² that is essential in transferring electrons to electron-transfer flavoprotein (ETF) in TMADH is not conserved in HADH. We use this structure to propose the binding mode for histamine in the active site of HADH through molecular modeling and to compare the interactions to those observed for other histamine-binding proteins whose structures are known.     

5-(2'-Pyridyl)-2-aminothiazoles: alkyl amino sulfonamides and sulfamides as potent NPY(5) antagonists

Synthesis, SAR and physico-chemical properties of an alkyl aminothiazole series 8 and 16 are described. 2-Pyridylaminothiazole based compounds such as 8c and 16a exhibit high affinity at the NPY₅ receptor with desirable c Log Ps and solubilities. However, they also suffer from high in vitro and in vivo clearance. Compound 16a partially inhibits the feeding behavior elicited by i.c.v. injection of the selective NPY₅ agonist [cPP^1-7, NPY^19-23, Ala³¹, Aib³², Gln³⁴]-human pancreatic polypeptide polypeptide (cPP).     

Understanding the allosteric trigger for the fructose-1,6-bisphosphate regulation of the ADP-glucose pyrophosphorylase from Escherichia coli

ADP-glucose pyrophosphorylase is the enzyme responsible for the regulation of glycogen synthesis in bacteria. The enzyme N-terminal domain has a Rossmann-like fold with three neighbor loops facing the substrate ATP. In the Escherichia coli enzyme, one of those loops also faces the regulatory site containing Lys³⁹, a residue involved in binding of the allosteric activator fructose-1,6-bisphosphate and its analog pyridoxal-phosphate. The other two loops contain Trp¹¹³ and Gln⁷⁴, respectively, which are highly conserved among all the ADP-glucose pyrophosphorylases. Molecular modeling of the E. coli enzyme showed that binding of ATP correlates with conformational changes of the latter two loops, going from an open to a closed (substrate-bound) form. Alanine mutants of Trp¹¹³ or Gln⁷⁴ did not change apparent affinities for the substrates, but they became insensitive to activation by fructose-1,6-bisphosphate. By capillary electrophoresis we found that the mutant enzymes still bind fructose-1,6-bisphosphate, with similar affinity as the wild type enzyme. Since the mutations did not alter binding of the activator, they must have disrupted the communication between the regulatory and the substrate sites. This agrees with a regulatory mechanism where the interaction with the allosteric activator triggers conformational changes at the level of loops containing residues Trp¹¹³ and Gln⁷⁴.     

Novel cathepsin L-like protease from dermestid beetle Dermestes frischii maggot

A novel cathepsin L-like protease from dermestid beetle Dermestes frischii maggot guts was obtained and investigated. The protease was isolated through affinity chromatography at arginine-diasorb followed by FPLC gel-filtration at Superdex 75. Protease is active against chromogenic peptide substrates, containing Arg or Leu in P1 position and a hydrophobic residue in P2 position. PH optimum is about 4,5 and temperature optimum at 40 °C. Enzyme is inhibited completely by HgCl₂ and leupeptin that prove it’s belonging to cysteine proteases of papain family.cDNA analysis of cathepsin L-like protease showed that protein sequence consists of 339 amino acid residues. Mature cysteine protease contains 219 amino acid residues corresponding to molecular mass 24027.20 Da. Residues of the active site were identified: Gln¹⁴⁰, Cys¹⁴⁶, His²⁸⁵, Asn³⁰⁶ and Trp³⁰⁸. Calculated pI is 4,73. The amino acid sequence of the cystein protease from dermestid beetle displays high structural homology with cathepsin L of other insects.     

Hemogloblin α-gene duplication in macaques: Individual Macaca nemestrina with three structurally different α chains

The diversity of hemoglobin phenotypes observed among Malaysian Macaca nemestrina (pig-tailed macaques) has been attributed, in part, to the presence of duplicated α-chain loci in some members of this species. To date, evidence in support of this view has been indirect, consisting of variation in proportions of α^I (Asp₇₁, Gln₇₈) and α^II (Asp₇₁, His₇₈) chains among presumptive heterozygotes. However, the discovery that erythrocytes from some M. nemestrina contain α^I and α^II chains in company with a third, or α^III, chain (Gly₇₁, Gln₇₈) provides direct evidence of duplicated α-chain loci.     

Neutral Proteinases I and II of Aspergillus sojae: Some Physicochemical Properties and Amino Acid Composition

Some physicochemical properties of neutral proteinases I and II, zinc-containing metalloenzymes, from Aspergillus sojae were investigated.

Neutral proteinase I: The enzyme protein had a sedimentation coefficient of 3.90S, an intrinsic viscosity of 0.0315 dl/g, and a partial specific volume, calculated from the amino acid and carbonhydrate composition, of 0.715 cm³/g. The molecular weight was 42,200 from the Yphantis’ procedure, and was 42,500 from the calculation according to the Scheraga-Mandel-kern’s formula. The integral numbers of amino acid residues per molecule calculated on the basis of 42,200 as molecular weight were as follows; Lys₁₆, His₆, Arg₁₃, Trp₈, Asp₅₆, Thr₂₅, Ser₂₃, Glu₃₁, Pro₁₈, Gly₄₀, Ala₃₃, l/2Cys₄, Val₁₁, Met₆, Ile₁₅, Leu₂₅, Tyr₂₀, Р?е₁₀, (amide-ammonia)₂₉, in addition to mannose₆, galactose₁, hexosamine₃.

Neutral proteinase II: The enzyme protein had a sedimentation coefficient of 2.32S, an intrinsic viscosity of 0.0270 dl/g, and a calculated partial specific volume of 0.714 cm³/g. The molecular weight was 16,800 from the Yphantis’ procedure, and was 18,000 from the sedimentation and intrinsic viscosity. The following amino acid compositions was calculated on the basis of 16,800 as molecular weight; Lys₈, His₃, Arg₃, Asp₁₉, Thr₁₇, Ser₁₁, GIu₂₃, Pro₅, Gly₉, Ala₂₄, l/2Cys₄, Val₅, Ile₃, Leu₁₃, Tyr₁₀, Phe₃, (amide-ammonia)₁₅. In the enzyme preparation, neither methionine nor tryptophan was detected and carbohydrate was also absent.

In both neutral proteinases I and II, no free SH group was detected by the PCMB-titration in the presence of 8 M urea.     

The localization of tRNA 5 Asn,tRNAHis, and tRNAAla genes from Drosophila melanogaster by in situ hybridization to polytene salivary gland chromosomes

Transfer RNA _5; ^Asn , tRNA _; ^His , and tRNA^Ala were isolated from Drosophila melanogaster by means of Sepharose 4B chromatography and 2-dimensional polyacrylamide gel electrophoresis. The tRNAs were iodinated in vitro with Na¹²⁵I and hybridized in situ to salivary gland chromosomes from Drosophila. Subsequent autoradiography allowed the localization of the genes for tRNA _5; ^Asn in the regions 42A, 59F, 60C, and 84F; for tRNA^His in the regions 48F and 56E; and for tRNA^Ala in the regions 63A and 90C. From these and our previous results it can be concluded that the genes for the Q-base containing tRNAs (tRNA^Asn, tRNA^Asp, and tRNA^His, are not clustered in the Drosophila melanogaster genome.     

Relative potency of the forms of GnRH and their analogs on LH release in sea bass

The in vivo and in vitro potency of native and modified forms of gonadotropin releasing hormone (GnRH) to release luteotropic hormone (LH) was studied in sea bass Dicentrarchus labrax in particular the hypothalamic fish‐specific sea bream GnRH form (sbGnRH) and the general mesoencephalic form chicken GnRH‐II (cGnRH‐II). The potencies of the natives and their analogs (GnRHas) were referred to that of [D‐Ala⁶, Pro⁹Net]‐mGnRHa (LHRHa) at equivalent doses. Analogs of the native peptides [D‐Arg⁶, Pro⁹Net]‐cGnRH‐II, [D‐Ala⁶, Pro⁹Net]‐cGnRH‐II, [D‐Trp⁶, Pro⁹Net]‐sbGnRH and [D‐Ala⁶, Pro⁹Net]‐sbGnRH were effective in inducing in vivo LH release (at 15 µg kg^?1 body mass), exhibiting longer lasting activity than their corresponding native forms. Injection of sbGnRH and cGnRH‐II provoked a small but significant peak of circulating LH at 1·5 h after treatment (a.t.) decreasing down to basal levels at 4 h a.t. [D‐Arg⁶, Pro⁹Net]‐cGnRH‐II, [D‐Ala⁶, Pro⁹Net]‐cGnRH‐II and [D‐Ala⁶, Pro⁹Net]‐mGnRHa evoked a higher and a more sustained elevation of LH, peaking at 12 h a.t. and returning to basal levels between 48 and 72 h a.t. [D‐Trp⁶, Pro⁹Net]‐sbGnRH and [D‐Ala⁶, Pro⁹Net]‐sbGnRH also induced a significant surge of LH in plasma at 4 h a.t. turning to the basal levels at 24 h a.t. These rises, however, were of less amplitude and duration than the observed after treatment with cGnRH‐II analogs and [D‐Ala⁶, Pro⁹Net]‐mGnRHa. The in vitro stimulation of dispersed pituitary cells with the different native and modified forms of GnRH resulted in a dose‐dependent increase in the quantity of LH released at 24 h a.t. [D‐Arg⁶, Pro⁹Net]‐cGnRH‐II and [D‐Ala⁶, Pro⁹Net]‐cGnRH‐II induced the highest response of LH in vitro release followed by salmon GnRH (sGnRH), [D‐Ala⁶, Pro⁹Net]‐mGnRHa and [D‐Trp⁶, Pro⁹Net]‐sbGnRH. The lowest activity was exhibited by sbGnRH. Collectively, the in vitro biological activity (compared by their EC₅₀) can be ordered as follows: [D‐Arg⁶, Pro⁹Net]‐cGnRH‐II > [D‐Ala⁶, Pro⁹Net]‐cGnRH‐II > sGnRH > [D‐Ala⁶, Pro⁹Net]‐mGnRHa > [D‐Trp⁶, Pro⁹Net]‐sbGnRH > [D‐Ala⁶, Pro⁹Net]‐sbGnRH > cGnRH‐II > sbGnRH.     

Partial structure and properties of the ferredoxin from Rhodymenia palmata

A ferredoxin of MW 11 000 was isolated from the marine alga Rhodymenia palmata (Palmaria palmata). In its oxidised form the ferredoxin had absorption maxima at 276, sh 281, 328, 423 and 465 nm, and contained a single [2Fe-2S] cluster. The midpoint potential of the ferredoxin was ?400 mV and it effectively mediated electron transport in NADP⁺-photoreduction by higher plant chloroplasts, and pyruvate decarboxylation by the phosphoroclastic system of an anacrobic bacterium. The amino acid composition was Lys₃, His₁, Arg₁, Asx₁₂, Thr₉, Ser₈, Glx₁₃, Pro₄, Gly₈, Ala₇, Cys₅, Val₈, Ile₄, Leu₉, Tyr₄, Phe₂; tryptophan and methionine were absent from the molecule. The N-terminal amino acid region consisting of ca half the total amino acid sequence was determined using an automatic sequencer.     

Histidine Residues in the Na+-coupled Ascorbic Acid Transporter-2 (SVCT2) Are Central Regulators of SVCT2 Function,Modulating pH Sensitivity,Transporter Kinetics,Na+ Cooperativity,Conformational Stability,and Subcellular Localization

Na⁺-coupled ascorbic acid transporter-2 (SVCT2) activity is impaired at acid pH, but little is known about the molecular determinants that define the transporter pH sensitivity. SVCT2 contains six histidine residues in its primary sequence, three of which are exofacial in the transporter secondary structure model. We used site-directed mutagenesis and treatment with diethylpyrocarbonate to identify histidine residues responsible for SVCT2 pH sensitivity. We conclude that five histidine residues, His¹⁰⁹, His²⁰³, His²⁰⁶, His²⁶⁹, and His⁴¹³, are central regulators of SVCT2 function, participating to different degrees in modulating pH sensitivity, transporter kinetics, Na⁺ cooperativity, conformational stability, and subcellular localization. Our results are compatible with a model in which (i) a single exofacial histidine residue, His⁴¹³, localized in the exofacial loop IV that connects transmembrane helices VII-VIII defines the pH sensitivity of SVCT2 through a mechanism involving a marked attenuation of the activation by Na⁺ and loss of Na⁺ cooperativity, which leads to a decreased V_max without altering the transport K_m; (ii) exofacial histidine residues His²⁰³, His²⁰⁶, and His⁴¹³ may be involved in maintaining a functional interaction between exofacial loops II and IV and influence the general folding of the transporter; (iii) histidines 203, 206, 269, and 413 affect the transporter kinetics by modulating the apparent transport K_m; and (iv) histidine 109, localized at the center of transmembrane helix I, might be fundamental for the interaction of SVCT2 with the transported substrate ascorbic acid. Thus, histidine residues are central regulators of SVCT2 function.