Recombinant phospholipase A<Subscript>1</Subscript> of the outer membrane of psychrotrophic <Emphasis Type="Italic">Yersinia pseudotuberculosis</Emphasis>: Expression,purification, and characterization

The pldA gene encoding membrane-bound phospholipase A₁ of Yersinia pseudotuberculosis was cloned and expressed in Escherichia coli cells. Recombinant phospholipase A₁ (rPldA) was isolated from inclusion bodies dissolved in 8 M urea by two-stage chromatography (ion-exchange and gel-filtration chromatography) as an inactive monomer. The molecular mass of the rPldA determined by MALDI-TOF MS was 31.7 ± 0.4 kDa. The highly purified rPldA was refolded by 10-fold dilution with buffer containing 10 mM Triton X-100 and subsequent incubation at room temperature for 16 h. The refolded rPldA hydrolyzed 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine in the presence of calcium ions. The enzyme exhibited maximal activity at 37°C and nearly 40% of maximal activity at 15°C. The phospholipase A₁ was active over a wide range of pH from 4 to 11, exhibiting maximal activity at pH 10. Spatial structure models of the monomer and the dimer of Y. pseudotuberculosis phospholipase A₁ were constructed, and functionally important amino acid residues of the enzyme were determined. Structural differences between phospholipases A₁ from Y. pseudotuberculosis and E. coli, which can affect the functional activity of the enzyme, were revealed.     

Revised Amino-acid Sequences for Porcine and Human Adrenocorticotrophic Hormone

MEMBRANE protein of bovine rod outer segments has been studied by gel electrophoresis and amino-acid analysis. Membranes were purified in a sucrose density gradient¹ at an ionic strength below 0.001. The isolated material probably consisted of fragmented disk membranes¹. ‘Emulphogene’ solutions of rhodopsin were chromatographed on calcium phosphate²; the results for A₂₇₈: A₄₉₈ were 1.7–1.8, indicating good purity.     

The effects of condensed tannins derived from senescing <Emphasis Type="Italic">Rhizophora mangle</Emphasis> leaves on carbon,nitrogen and phosphorus mineralization in a <Emphasis Type="Italic">Distichlis spicata</Emphasis> salt marsh soil

Background and aims

Low nitrogen negatively affects soil fertility and plant productivity. Glucose-6-phosphate dehydrogenase (G6PDH) and Epichloë gansuensis endophytes are two factors that are associated with tolerance of Achnatherum inebrians to abiotic stress. However, the possibility that E. gansuensis interacts with G6PDH in enhancing low nitrogen tolerance of host grasses has not been examined.

Methods

A. inebrians plants with (E+) and without E. gansuensis (E?) were subjected to different nitrogen concentration treatments (0.1, 1, and 7.5 mM). After 90 days, physiological studies were carried out to investigate the participation of G6PDH in the adaption of host plants to low nitrogen availability.

Results

Low nitrogen retarded the growth of A. inebrians. E+ plants had higher total dry weight, chlorophyll a and b contents, net photosynthesis rate, G6PDH activity, and GSH content, while having lower plasma membrane (PM) NADPH oxidase activity, NADPH/NADP⁺ ratios, and MDA and H₂O₂ than in E? A. inebrians plants under low nitrogen concentration.

Conclusions

The presence of E. gansuensis played a key role in maintaining the growth of the A. inebrians plants under low nitrogen concentration by regulating G6PDH activity and the NADPH/NADP⁺ ratio and improving net photosynthesis rate.

     

Sucrose dependent mineral phosphate solubilization in <Emphasis Type="Italic">Enterobacter asburiae</Emphasis> PSI3 by heterologous overexpression of periplasmic invertases

Enterobacter asburiae PSI3 solubilizes mineral phosphates in the presence of glucose by the secretion of gluconic acid generated by the action of a periplasmic pyrroloquinoline quinone dependent glucose dehydrogenase. In order to achieve mineral phosphate solubilization phenotype in the presence of sucrose, plasmids pCNK4 and pCNK5 containing genes encoding the invertase enzyme of Zymomonas mobilis (invB) and of Saccharomyces cerevisiae (suc2) under constitutive promoters were constructed with malE signal sequence (in case of invB alone as the suc2 is secreted natively). When introduced into E. asburiae PSI3, E. a. (pCNK4) and E. a. (pCNK5) transformants secreted 21.65 ± 0.94 and 22 ± 1.3 mM gluconic acid, respectively, in the presence of 75 mM sucrose and they also solubilized 180 ± 4.3 and 438 ± 7.3 µM P from the rock phosphate. In the presence of a mixture of 50 mM sucrose and 25 mM glucose, E. a. (pCNK5) secreted 34 ± 2.3 mM gluconic acid and released 479 ± 8.1 µM P. Moreover, in the presence of a mixture of eight sugars (10 mM each) in the medium, E. a. (pCNK5) released 414 ± 5.3 µM P in the buffered medium. Thus, this study demonstrates incorporation of periplasmic invertase imparted P solubilization ability to E. asburiae PSI3 in the presence of sucrose and mixture of sugars.     

Isolation and Characterisation of Insulin-Releasing Compounds from <Emphasis Type="Italic">Pseudechis australis</Emphasis> and <Emphasis Type="Italic">Pseudechis butleri</Emphasis> Venom

Crude venom from two elapid snakes Pseudechis australis and Pseudechis butleri was fractionated by gel filtration chromatography and selected fractions screened for in vitro insulin-releasing activity using clonal pancreatic BRIN-BD11 cells. Following acute 20-min incubation at 5.6 mM glucose, 9 fractions exhibited significant (P < 0.001) insulin-releasing activity. Structural characterisation of active fractions was achieved primarily using MALDI–TOF MS and N-terminal Edman degradation sequencing. The partial N-terminal sequences are reported for a total of 7 venom components. Their homology to existing sequences as determined using BLAST searching uncovered the main insulin-releasing families as being phospholipases A₂ and short α-neurotoxins. A number of sequences are reported for the first time from P. butleri venom which is much less studied than the related P. australis.     

Relation between various phospholipase actions on human red cell membranes and the interfacial phospholipid pressure in monolayers

The action of purified phospholipases on monomolecular films of various interfacial pressures is compared with the action on erythrocyte membranes. The phospholipases which cannot hydrolyse phospholipids of the intact erythrocyte membrane, phospholipase C from Bacillus cereus, phospholipase A₂ from pig pancreas and Crotalus adamanteus and phospholipase D from cabbage, can hydrolyse phospholipid monolayers at pressure below 31 dynes/cm only.The phospholipases which can hydrolyse phospholipids of the intact erythrocyte membrane, phospholipase C from Clostridium welchii phospholipase A₂ from Naja naja and bee venom and sphingomyelinase from Staphylococcus aureus, can hydrolyse phospholipid monolayers at pressure above 31 dynes/cm. It is concluded that the lipid packing in the outer monolayer of the erythrocyte membrane is comparable with a lateral surface pressure between 31 and 34.8 dynes/cm.     

Simple and inexpensive Flow Injection Analysis for determination of sucrose using invertase and glucose oxidase immobilised on glass beads

A Flow Injection Analysis (FIA) for sucrose using invertase (E.C. 3.2.1.26), mutarotase (E.C.5.1.3.3) and glucose oxidase (E.C.1.1.3.4) was developed. The enzymes were immobilised on glass beads using glutaraldehyde. The sucrose concentration was related to oxygen saturation. Fall in O₂ concentration, as a result of sucrose oxidation, was detected by a low cost, home-made O₂ electrode. The system was able to measure sucrose from 0.025 to 100mM with a response time of 6min using 200 l of sample, with an apparent Km of 42mM of sucrose. The system has been operated satisfactorily for 50 days without loss any initial activity.     

Escherichia coli K-12 Suppressor-free Mutants Lacking Early Glycosyltransferases and Late Acyltransferases: MINIMAL LIPOPOLYSACCHARIDE STRUCTURE AND INDUCTION OF ENVELOPE STRESS RESPONSE*

To elucidate the minimal lipopolysaccharide (LPS) structure needed for the viability of Escherichia coli, suppressor-free strains lacking either the 3-deoxy-d-manno-oct-2-ulosonic acid transferase waaA gene or derivatives of the heptosyltransferase I waaC deletion with lack of one or all late acyltransferases (lpxL/M/P) and/or various outer membrane biogenesis factors were constructed. Δ(waaC lpxL lpxM lpxP) and waaA mutants exhibited highly attenuated growth, whereas simultaneous deletion of waaC and surA was lethal. Analyses of LPS of suppressor-free waaA mutants grown at 21 °C, besides showing accumulation of free lipid IV_A precursor, also revealed the presence of its pentaacylated and hexaacylated derivatives, indicating in vivo late acylation can occur without Kdo. In contrast, LPS of Δ(waaC lpxL lpxM lpxP) strains showed primarily Kdo₂-lipid IV_A, indicating that these minimal LPS structures are sufficient to support growth of E. coli under slow-growth conditions at 21/23 °C. These lipid IV_A derivatives could be modified biosynthetically by phosphoethanolamine, but not by 4-amino-4-deoxy-l-arabinose, indicating export defects of such minimal LPS. ΔwaaA and Δ(waaC lpxL lpxM lpxP) exhibited cell-division defects with a decrease in the levels of FtsZ and OMP-folding factor PpiD. These mutations led to strong constitutive additive induction of envelope responsive CpxR/A and σ^E signal transduction pathways. Δ(lpxL lpxM lpxP) mutant, with intact waaC, synthesized tetraacylated lipid A and constitutively incorporated a third Kdo in growth medium inducing synthesis of P-EtN and l-Ara4N. Overexpression of msbA restored growth of Δ(lpxL lpxM lpxP) under fast-growing conditions, but only partially that of the Δ(waaC lpxL lpxM lpxP) mutant. This suppression could be alleviated by overexpression of certain mutant msbA alleles or the single-copy chromosomal MsbA-498V variant in the vicinity of Walker-box II.Lipopolysacharides (LPS)4 are the major amphiphilic constituents of the outer leaflet of the outer membrane (OM) of Gram-negative bacteria, including Escherichia coli. LPS share a common architecture composed of a membrane-anchored phosphorylated and acylated β(1→6)-linked GlcN disaccharide, termed lipid A, to which a carbohydrate moiety of varying size is attached (1, 2). The latter may be divided into a lipid A proximal core oligosaccharide and, in smooth-type bacteria, a distal O-antigen. LPS always contain 3-deoxy-α-d-manno-oct-2-ulosonic acid (Kdo) linked to the lipid A.The physiological importance of the Kdo/lipid A region is reflected by its specific position within the pathway of LPS biosynthesis. In E. coli K-12, a bisphosphorylated lipid A precursor molecule with two amide and two ester-bound (R)-3-hydroxymyristate residues (lipid IV_A) is synthesized from UDP-GlcNAc, following 6 distinct enzyme reactions (1). This intermediate serves as an acceptor for the Kdo transferase (WaaA), which transfers two Kdo residues from CMP-Kdo to yield an α(2→4)-linked Kdo disaccharide-attached α(2→6) to the non-reducing GlcN residue of lipid IV_A (3). The latter reaction product, termed Kdo₂-lipid IV_A, comprises a key intermediate of LPS biosynthesis that acts 2-fold as a specific substrate: (i) for glycosyltransferases catalyzing further steps of the core oligosaccharide biosynthesis (4) and (ii) for acyltransferases that complete the lipid A moiety by the transfer of 2 additional fatty acids to the (R)-3-hydroxyl groups of both acyl chains, which are directly bound to position 2′ and 3′ of the non-reducing GlcN residue (1). Three acyltransferases, encoded by paralogous genes, have been described in E. coli K-12, which catalyze the latter enzyme reactions using acyl carrier protein-activated fatty acids as co-substrates (5–10). At ambient temperatures, a lauroyl residue is first transferred by LpxL (6) to the OH group of the amide-bound (R)-3-hydroxymyristate residue at position 2′. This catalytic step is partially replaced at low temperature (12 °C) by LpxP, which transfers palmitoleate to the same position in ∼80% of the LPS molecules (7). The free OH group of the ester-bound (R)-3-hydroxymyristate residue at position 3′ within both pentaacylated intermediates is then myristoylated by LpxM to give a hexaacylated lipid A moiety (Fig. 3) (5).Open in a separate windowFIGURE 3.Chemical structure of tetraacylated lipid IV_A precursor (A) and Kdo₂-lipid IV_A (B). R1 represents C12:0 or C16:1; R2, C14:0; R3 and R4 are under LPS-modifying conditions P-EtN and l-Ara4N, respectively, and R5, C16:0.Consistent with the essentiality of LPS in E. coli, all the genes, whose products are required for committed steps of biosynthesis of lipid IV_A and subsequent transfer of Kdo to it, are essential (1, 2). However, individually neither the subsequent steps of addition of the secondary lauroyl and myristoyl residues to the distal glucosoamine unit by LpxL and LpxM to synthesize hexaacylated lipid A nor the later glycosylation of hexaacylated Kdo₂-lipid A is essential for viability of bacteria like E. coli K-12 under defined growth conditions (8). Although Re mutants that possess LPS with only hexaacylated Kdo₂-lipid A or mutants that synthesize complete LPS core with only lipid IV_A are viable, they are impaired in several growth properties, including constitutive induction of RpoE signal transduction in Re mutants (8, 11–13). A triple null mutant, which lacks all 3 late acyltransferases, is viable but only in slow-growth conditions in accordance with lipid IV_A being a poor substrate of the lipid A transporter MsbA (8). Mutants impaired in the synthesis of Kdo, which synthesize only lipid IV_A lacking any glycosylation, can be constructed, but they require additional suppressor mutations either in msbA, or the yhjD gene (14, 15). Strains that potentially can only synthesize Kdo₂-lipid IV_A have not been reported up to now. Thus, suppressor-free minimal LPS structures that can support growth of E. coli K-12 bacteria known up to now have genetic compositions of Δ(lpxL lpxM lpxP) or Re mutants.We describe the construction and characterization of suppressor-free ΔwaaA and Δ(waaC lpxL lpxM lpxP) mutants, synthesizing either free lipid IV_A derivatives or Kdo₂-lipid IV_A LPS, respectively. Analyses of lipid A of ΔwaaA also revealed the presence of free penta- and hexaacylated lipid A derivatives, arising due to incorporation of secondary acyl chains. Such suppressor-free strains could be constructed only in slow-growth conditions at lower temperatures. Growth of Δ(waaC lpxL lpxM lpxP) could be restored by extragenic chromosomal MsbA-D498V suppressor mutation or by the overexpression of the msbA wild-type gene product. The LPS of Δ(waaC lpxL lpxM lpxP) and lipid IV_A precursor of ΔwaaA was found to be substituted by P-EtN, but not l-Ara4N, under LPS-modifying growth conditions. Deletion of late acyltransferases in ΔwaaC or deletion of the waaA gene resulted in constitutively elevated levels of periplasmic protease HtrA, due to additive induction of the envelope stress responsive CpxR/A two-component system and σ^E pathway.     

Interaction of various types of photosystem I complexes with exogenous electron acceptors

Interaction of photosystem I (PS I) complexes from cyanobacteria Synechocystis sp. PCC 6803 containing various quinones in the A₁-site (phylloquinone PhQ in the wild-type strain (WT), and plastoquinone PQ or 2,3-dichloronaphthoquinone Cl ₂ NQ in the menB deletion strain) and different numbers of Fe₄S₄ clusters (intact WT and F_X-core complexes depleted of F_A/F_B centers) with external acceptors has been studied. The efficiency of interaction was estimated by measuring the light-induced absorption changes at 820 nm due to the reduction of the special pair of chlorophylls (P₇₀₀ ⁺) by an external acceptor(s). It was shown that externally added Cl ₂ NQ is able to effectively accept electrons from the terminal iron-sulfur clusters of PS I. Moreover, the efficiency of Cl ₂ NQ as external acceptor was higher than the efficiency of the commonly used artificial electron acceptor, methylviologen (MV) for both the intact WT PS I and for the F_X-core complexes. The comparison of the efficiency of MV interaction with different types of PS I complexes revealed gradual decrease in the following order: intact WT?>?menB?>?F_X-core. The effect of MV on the recombination kinetics in menB complexes of PS I with Cl ₂ NQ in the A₁-site differed significantly from all other PS I samples. The obtained effects are considered in terms of kinetic efficiency of electron acceptors in relation to thermodynamic and structural characteristics of PS I complexes.     

Influence of Daily Short-Term Temperature Drops on Respiration to Photosynthesis Ratio in Chilling-Sensitive Plants

Cucumber (Cucumis sativus L.), tomato (Solanum lycopersicum L.), and sweet pepper (Capsicum annuum L.) plants were subjected daily over 13 days to short-term (2 h) temperature drops to 12, 8, 4, and 1°C (DROP treatments) at the end of night periods, and effects of these chilling treatments on the ratio of dark respiration in leaves (R_d) to gross photosynthesis (A_g) were examined. The results showed that DROP treatments affected the R_d/A_g ratio in leaves: this ratio increased significantly in cucumber and tomato plants and was slightly affected in pepper plants. When the temperature drops to 12°C were applied, the increase in R_d/A_g ratio in cucumber and tomato plants was entirely due to the rise in R_d. In the case of temperature drops to 8°C and below, the increase in R_d/A_g was determined by both elevation of R_d and the concurrent decrease in Ag. In cucumber plants, the extent of Ag and R_d changes increased with the DROP severity, i.e., with lowering the temperature of DROP treatment. The inhibition of photosynthesis by DROP treatment in cucumber plants was accompanied by the diminished efficiency of light energy use for photosynthesis and by the increase in the light compensation point. The elevation in R_d/A_g ratio in cucumber plants was accompanied by the decline in growth characteristics, such as accumulation of aboveground biomass, plant height, and leaf area. It was concluded that the R/A ratio is an important indicator characterizing the adaptive potential of chilling-sensitive plant species and their response to daily short-term temperature drops.     

Domain Architecture of the Stator Complex of the A1A0-ATP Synthase from Thermoplasma acidophilum

A key structural element in the ion translocating F-, A-, and V-ATPases is the peripheral stalk, an assembly of two polypeptides that provides a structural link between the ATPase and ion channel domains. Previously, we have characterized the peripheral stalk forming subunits E and H of the A-ATPase from Thermoplasma acidophilum and demonstrated that the two polypeptides interact to form a stable heterodimer with 1:1 stoichiometry (Kish-Trier, E., Briere, L. K., Dunn, S. D., and Wilkens, S. (2008) J. Mol. Biol. 375, 673–685). To define the domain architecture of the A-ATPase peripheral stalk, we have now generated truncated versions of the E and H subunits and analyzed their ability to bind each other. The data show that the N termini of the subunits form an α-helical coiled-coil, ∼80 residues in length, whereas the C-terminal residues interact to form a globular domain containingα- and β-structure. We find that the isolated C-terminal domain of the E subunit exists as a dimer in solution, consistent with a recent crystal structure of the related Pyrococcus horikoshii A-ATPase E subunit (Lokanath, N. K., Matsuura, Y., Kuroishi, C., Takahashi, N., and Kunishima, N. (2007) J. Mol. Biol. 366, 933–944). However, upon the addition of a peptide comprising the C-terminal 21 residues of the H subunit (or full-length H subunit), dimeric E subunit C-terminal domain dissociates to form a 1:1 heterodimer. NMR spectroscopy was used to show that H subunit C-terminal peptide binds to E subunit C-terminal domain via the terminal α-helices, with little involvement of the β-sheet region. Based on these data, we propose a structural model of the A-ATPase peripheral stalk.The archaeal ATP synthase (A₁A₀-ATPase),² along with the related F₁F₀- and V₁V₀-ATPases (proton pumping vacuolar ATPases), is a rotary molecular motor (1–4). The rotary ATPases are bilobular in overall architecture, with one lobe comprising the water-soluble A₁, F₁, or V₁ and the other comprising the membrane-bound A₀, F₀, or V₀ domain, respectively. The subunit composition of the A-ATPase is A₃B₃DE₂FH₂ for the A₁ and CIK_x for the A₀. In the A₁ domain, the three A and B subunits come together in an alternating fashion to form a hexamer with a hydrophobic inner cavity into which part of the D subunit is inserted. Subunits D and F comprise the central stalk connection to A₀, whereas two heterodimeric EH complexes are thought to form the peripheral stalk attachment to A₀ seen in electron microscopy reconstructions (5, 6). In the A₀ domain (subunits CIK_x), the K subunits (proteolipids) form a ring that is linked to the central stalk by the C subunit, whereas the cytoplasmic N-terminal domain of the I subunit probably mediates the binding of the EH peripheral stalks to A₀, as suggested for the bacterial A/V-type enzyme (7). Although closer in structure to the proton-pumping V-ATPase, the A-ATPase functions in vivo as an ATP synthase, coupling ion motive force to ATP synthesis, most likely via a similar rotary mechanism as demonstrated for the bacterial A/V- and the vacuolar type enzymes (8, 9). During catalysis, substrate binding occurs sequentially on the three catalytic sites, which are formed predominantly by the A subunits. This is accompanied by conformation changes in the A₃B₃ hexamer that are linked to the rotation of the embedded D subunit together with the rotor subunits F, C, and the proteolipid ring. Each copy of K contains a lipid-exposed carboxyl residue (Asp or Glu), which is transiently interfaced with the membrane-bound domain of I during rotation, thereby catalyzing ion translocation. The EH peripheral stalks function to stabilize the A₃B₃ hexamer against the torque generated during rotation of the central stalk. Much work has been accomplished to elucidate the architectural features of the rotational and catalytic domains, especially in the related F- and V-type enzymes. However, the peripheral stalk complexes in the A- and V-type enzymes remain an area open to question. Although the stoichiometry of the peripheral stalks in the A/V-type and the vacuolar type ATPases have recently been resolved to two and three, respectively (6, 10), the overall structure of the peripheral stalk, including the nature of attachment to the A₃B₃ hexamer and I subunit (called subunit a in the F- and V-ATPase), is not well understood. Some structural information exists in the form of the A-ATPase E subunit C-terminal domain (11), although isolation from its binding partner H may have influenced its conformation.Previously, our lab has characterized the Thermoplasma acidophilum A-ATPase E and H subunits individually and in complex (12). We found that despite their tendency to oligomerize when isolated separately, upon mixing, E and H form a tight heterodimer that was monodisperse and elongated in solution, which is consistent with its role as the peripheral stalk element in the A-ATPase. Here, we have expanded our study of the A-ATPase EH complex through the production of various N- and C-terminal truncation mutants of both binding partners. The data show that the EH complex is comprised of two distinct domains, one that contains both N termini interacting via a coiled-coil and a second that contains both C termini folded in a globular structure containing mixed secondary structure. Consistent with recent crystallographic data for the related A-ATPase from Pyrococcus horikoshii (11), we found that the isolated C-terminal domain of the E subunit exists as a stable homodimer in solution. However, the addition of subunit H or a peptide consisting of the 21 C-terminal residues of the subunit to the dimeric C-terminal domain of subunit E resulted in dissociation of the homodimer with concomitant formation of a 1:1 heterodimer containing the C termini of both polypeptides. This study delineates and characterizes the two domains of the EH complex and will aid in the further exploration of the nature of peripheral stalk attachment and function in the intact A₁A₀-ATPase.     

Effect of outer sphere anions on the structure and color of nitrosylpentaamminechromium complex

Three kinds of crystalline compounds containing the nitrosylpentaamminechromium complexes [Cr(NO)(NH₃)₅]²⁺(A) were obtained: chloride ACl₂ (red-orange), chloride perchlorate ACl(ClO₄) (brown), and perchlorate A(ClO₄)₂ (green). The cause of the color change of the complex A with the change of outer sphere anions was sought using X-ray structural data of ACl₂, ACl(ClO₄), and A(ClO₄)₂. Crystal data: ACl₂, orthorhombic, space group Cmcm, a=10.0236 (9) Å, b=9.098 (3) Å, c=10.357(1) Å, V=944.5 (5) ų, Z=4; ACl(ClO₄), tetragonal, space group P4/nmm, a=7.6986 (8) Å, c=9.9566(8) Å, V=590.1 (1) Å^3,Z=2; A(ClO₄)₂, orthorhombic, space group Pnma, a=15.760 (2) Å, b=11.480(2) Å, c=7.920 (2) Å, V=1432.9 (4) ų, Z=4. The complex cation in ACl₂ has a distorted octahedral structure with a linear CrNO moiety. The short CrN (nitrosyl) distance of 1.692 (7) Å indicates the presence of multiple bonding between the chromium atom and the nitrogen atom in the nitrosyl group. The interatomic distances and angles within the complex cations hardly change with the change of the counter anions, while the distances between the complex cations in each crystal increase in the order ACl₂<ACl(ClO₄)<A(ClO₄)₂. The bulky perchlorate anions seems to separate the complex cations, while smaller chloride anions are not large enough to separate them. The distance (3.213(5) Å) between O(NO) and N(NH₃ in the adjacent complex cation) is rather short in the crystal of ACl₂, and there are six hydrogen bonds, where the NO group is surrounded by four NH₃ ligands. The distance (4.002(5) Å) between O(NO) and N(NH₃) is much longer in the crystal of A(ClO₄)₂, indicating the presence of no hydrogen bonding. In the crystal of ACl(ClO₄) the distance (3.452(4) Å) between O(NO) and N(NH₃) is in between those of ACl₂ and A(ClO₄)₂. The presence of hydrogen bonding between O(NO) and N(NH₃ in the adjacent complex cation) seems to cause the color change with the change of outer sphere anions.     

Characterization flavanone 3β-hydroxylase expressed from <Emphasis Type="Italic">Populus euphratica</Emphasis> in <Emphasis Type="Italic">Escherichia coli</Emphasis> and its application in dihydroflavonol production

Flavanone 3β-hydroxylase plays very important role in the biosynthesis of flavonoids. A putative flavanone 3β-hydroxylase gene (Pef3h) from Populus euphratica was cloned and over-expressed in Escherichia coli. Induction performed with 0.1 mM IPTG at 20°C led to localization of PeF3H in the soluble fraction. Recombinant enzyme was purified by Ni-NTA affinity. The optimal activity of PeF3H was revealed at pH 7.6 and 35°C. The purified enzyme was stable over pH range of 7.6–8.8 and had a half-life of 1 h at 50°C. The activity of PeF3H was significantly enhanced in the presence of Fe²⁺ and Fe³⁺. The K _M and V _max for the enzyme using naringenin as substrate were 0.23 mM and 0.069 μmoles mg–1min-1, respectively. The K _m and V _max for eriodictyol were 0.18 mM and 0.013 μmoles mg^–1min^–1, respectively. The optimal conditions for naringenin bioconversion in dihydrokaempferol were obtained: OD₆₀₀ of 3.5 for cell concentration, 0.1 mM IPTG, 5 mM α-ketoglutaric acid and 20°C. Under the optimal conditions, naringenin (0.2 g/L) was transformed into 0.18 g/L dihydrokaempferol within 24 h by the recombinant E. coli with a corresponding molar conversion of 88%. Thus, this study provides a promising flavanone 3β-hydroxylase that may be used in biosynthetic applications.     

Emergence of acetylcholine resistance and loss of rhythmic activity associated with the development of hypertension,obesity, and type 2 diabetes

The aim of this work was to study the influence of aging, obesity, metabolic syndrome (MS), hypertension (HT), and type 2 diabetes (T2D) on the endogenous rhythmic activity and the development acetylcholine resistance in aorta rings of male rats. T2D was produced by a free access to fat (lard). It was shown that phenylephrine (PE) or 5-hydroxytryptamine (5-HT) induces two types of rhythmic contractions: with periods T ₁ = 3–10 s and T ₂ = 50–70 s and amplitudes A ₁ = 1–5% and A ₂ = 20–40% of the maximal contraction force (F _max), respectively. Such periodic modes can be caused by the operation of two known positive feedback loops (PFL) based on the Ca²⁺-induced activation of IP3 receptor (IP3R) or phospholipase C PFL1 and PFL2, respectively, and are not eliminated by L-NAME. Slow rhythmic activity induced by acetylcholine (Ach) with period T ₃ = 7–20 min and amplitude A ₃ = 20–30% of F _max was observed only in young animals (under 6 months) and can be determined by the operation of PFL3, involving Ca²⁺, NO, kinase G, cADP-ribose, and the ryanodine receptor (RyR). Fast mode of contractions (T ₁, A ₁) is maintained regardless of age and the presence of MS and HT (140 mm Hg and higher) and disappears only at later stages of the T2D development. Probability of intermediate mode of contractions (T ₂, A ₂) decreases to 0.20–0.25 at the age of 14–16 months or during the development of HT and MS. In these circumstances, Ach could cause relaxation of preconstricted rings only to 40 and 60% of F _max, respectively. At the stages of the T2D development characterized by high values of arterial pressure (above 150 mm Hg) and of the glucose (10–12 mM), ammonium (120–180 μM), and blood lipid levels, as well as by liver dysfunction (fibrosis/cirrhosis), the rhythmic activity of any type is lost and dysfunction of the initial part of the signaling cascade with the participation of PFL3 is manifested by the absence of responses to Ach or L-NAME. Coenzyme NAD (agonist of the P2Y receptors, К⁺ channel activator and a precursor of cADP-ribose) can exert a partial relaxation of aorta rings from healthy animals and animals with MS. Nicotinamide (product and an inhibitor of ADP-ribosyl cyclase) and SNP (donor of NO) produce an effective relaxation of aorta rings from healthy animals and animals with T2D. Relaxing effect of nicotinamide may suggest a tandem operation of IP3R and RyR in the control of intracellular Ca²⁺ stores in vascular cells.