Direct Covalent Biomolecule Immobilization on Plasma-Nanotextured Chemically Stable Substrates.

A new method for direct covalent immobilization of protein molecules (including antibodies) on organic polymers with plasma-induced random micronanoscale topography and stable-in-time chemical functionality is presented. This is achieved using a short (1-5 min) plasma etching and simultaneous micronanotexturing process, followed by a fast thermal annealing step, which induces accelerated hydrophobic recovery while preserving important chemical functionality created by the plasma. Surface-bound biomolecules resist harsh washing with sodium dodecyl sulfate and other detergents even at elevated temperatures, losing less than 40% of the biomolecules bound even at the harshest washing conditions. X-ray photoelectron spectroscopy, secondary-ion mass spectrometry, and electron paramagnetic resonance are used to unveil the chemical modification of the plasma-treated and stabilized surfaces. The nanotextured and chemically stabilized surfaces are used as substrates for the development of immunochemical assays for the sensitive detection of C-reactive protein and salmonella lipopolysaccharides through immobilization of the respective analyte-specific antibodies onto them. Such substrates are stable for a period of 1 year with ambient storage.

Changes in the LHCII-mediated energy utilization and dissipation adjust the methanol-induced biomass increase.

Considerably low methanol concentrations of 0.5% (v/v), induce an immense increase in biomass production in cultures of the unicellular green alga Scenedesmus obliquus compared to controls without additional methanol. The effect is light-regulated and it mimics high-CO2 induced changes of the molecular structure and function of the photosynthetic apparatus. There is evidence that methanol enhances under high light conditions by molecular changes in the LHCII--a decrease of the functional antenna-size per active reaction center--the photochemical effectiveness of the absorbed energy. This means that the non-photochemical quenching (NPQ) is minimized and thereby the overall dissipation energy. Experiments with mutants of Scenedesmus Wt produced evidence that the LHCII is the locus of the mechanism which regulates the methanol effect. The employed mutants were Wt-LHC, lacking a functioning LHCII, the light-dependent greening mutant C-2A', and the double mutant C-2A'-LHC, combining both mutations.

Isolation and spectroscopic characterization of a recombinant bell pepper hydroperoxide lyase.

Fatty acid hydroperoxide (HPO) lyase is a component of the oxylipin pathway and holds a central role in elicited plant defense. HPO lyase from bell pepper has been identified as a heme protein which shares 40% homology with allene oxide synthase, a cytochrome P450 (CYP74A). HPO lyase of immature bell pepper fruits was expressed in Escherichia coli and the enzyme was purified and characterized by spectroscopic techniques. The electronic structure and ligand coordination properties of the heme were investigated by using a series of exogenous ligands. The various complexes were characterized by using UV-visible absorption and electron paramagnetic resonance spectroscopy. The spectroscopic data demonstrated that the isolated recombinant HPO lyase has a pentacoordinate, high-spin heme with thiolate ligation. Addition of the neutral ligand imidazole or the anionic ligand cyanide results in the formation of hexacoordinate adducts that retain thiolate ligation. The striking similarities between both the ferric and ferrous HPO lyase-NO complexes with the analogous P450 complexes, suggest that the active sites of HPO lyase and P450 share common structural features.

Combination of reduced oxygen tension and intermittent hydrostatic pressure: a useful tool in articular cartilage tissue engineering.

Cartilage cells are normally studied under atmospheric pressure conditions and without loading. However, since cartilage exists in a condition of reduced oxygen and intermittent hydrostatic pressure we hypothesized lower partial oxygen pressures (PO2) and different intermittent hydrostatic pressures (IHP) would increase articular chondrocyte proliferation and matrix production and to stabilize chondrocyte phenotype in vitro. Monolayers of adult bovine articular chondrocytes were cultured under 5% or 21% PO2 in combination with IHP (0.2 MPa amplitude, frequencies 5/5s = 0.1 Hz, 30/2 or 2/30 min on/off loading). We measured proliferation (3H-thymidine incorporation) and collagen secretion (protein-binding assay, collagen type II-ELISA and immunocytochemical staining of pericellular collagen types I, II and IX). Reduced PO2 stimulated proliferation and collagen type II and IX secretion of chondrocytes in comparison to 21% PO2. Additionally, collagen type I expression was delayed by low PO2, indicating a stabilization of the cell phenotype. IHP 5/5s and 30/2 min inhibited proliferation but increased collagen secretion (pericellular collagen type IX was decreased). IHP 30/2 min delayed first expression of collagen type I. In contrast, IHP 2/30 min increased proliferation, but lowered collagen expression. All stimulating or inhibiting effects of PO2 and IHP were additive and vice versa. Reduced PO2 and different settings of IHP increased proliferation, collagen secretion, and phenotype stability of chondrocytes. The oxygen- and IHP-induced effects were additive, suggesting that a combination of these parameters might be a useful tool in cartilage tissue engineering.

Flavohemoglobin Hmp affords inducible protection for Escherichia coli respiration, catalyzed by cytochromes bo' or bd, from nitric oxide.

Respiration of Escherichia coli catalyzed either by cytochrome bo' or bd is sensitive to micromolar extracellular NO; extensive, transient inhibition of respiration increases as dissolved oxygen tension in the medium decreases. At low oxygen concentrations (25-33 microm), the duration of inhibition of respiration by 9 microm NO is increased by mutation of either oxidase. Respiration of an hmp mutant defective in flavohemoglobin (Hmp) synthesis is extremely NO-sensitive (I(50) about 0.8 microm); conversely, cells pre-grown with sodium nitroprusside or overexpressing plasmid-borne hmp(+) are insensitive to 60 microm NO and have elevated levels of immunologically detectable Hmp. Purified Hmp consumes O(2) at a rate that is instantaneously and extensively (>10-fold) stimulated by NO due to NO oxygenase activity but, in the absence of NO, Hmp does not contribute measurably to cell oxygen consumption. Cyanide binds to Hmp (K(d) 3 microm). Concentrations of KCN (100 microm) that do not significantly inhibit cell respiration markedly suppress the protection of respiration from NO afforded by Hmp and abolish NO oxygenase activity of purified Hmp. The results demonstrate the role of Hmp in protecting respiration from NO stress and are discussed in relation to the energy metabolism of E. coli in natural O(2)-depleted environments.

Interaction of nitric oxide with the oxygen evolving complex of photosystem II and manganese catalase: a comparative study.

We compare the interaction of nitric oxide with the S states of the oxygen evolving complex (OEC) of photosystem II and the dinuclear Mn cluster of Thermus thermophilus catalase. Flash fluorescence studies indicate that the S3 state of the OEC in the presence of ca. 0.6 mM NO is reduced to the S1 with an apparent halftime of ca. 0.4 s at about 18 degrees C, compared with a biphasic decay, with approximate halftimes of 28 s for S3 to S2 and 140 s for S2 to S1 in the absence of NO. Under similar conditions the S2 state is reduced by NO to the S1 state with an approximate halftime of 2 s. These results extend a recent study indicating a slow reduction of the S1 state at -30 degrees C, via the S0 and S(-1) states, to a Mn(II)-Mn(III) state resembling the corresponding state in catalase. The reductive mode of action of NO is repeated with the di-Mn cluster of catalase: the Mn(III)-Mn(III) redox state is reduced to the Mn(II)-Mn(II) state via the intermediate Mn(II)-Mn(III) state. The kinetics of this reduction suggest a decreasing reduction potential with decreasing oxidation state, similar to what is observed with the active states of the OEC. What is unique about the OEC is the rapid interaction of NO with the S3 state of the OEC, which is compatible with a metalloradical character of this state.

Electron paramagnetic resonance signals from the S(3) state of the oxygen-evolving complex. A broadened radical signal induced by low-temperature near-infrared light illumination.

The tetranuclear manganese cluster responsible for the oxidation of water in photosystem II cycles through five redox states denoted S(i)() (i = 0, 1, 2, 3, 4). Progress has been made recently in the detection of weak low-field EPR absorptions in both the perpendicular and parallel modes, associated with the integer spin state S(3) [Matsukawa, T., Mino, H., Yoneda, D., and Kawamori, A. (1999) Biochemistry 38, 4072-4077]. We confirm observation of these signals and have obtained them in high yield by illumination of photosystem II membranes, in which the non-heme iron was chemically preoxidized. It is shown that a split g = 4 signal accompanies the S(3) state signals. The signals diminish in the presence of ethanol and vanish in the presence of methanol. This effect is similar to that exerted by these alcohols to the high-spin component (g = 4.1) of the S(2) state and suggests that the latter spin configuration is the precursor of the S(3) state low-field signals. The S(3) state shows similar sensitivity to infrared illumination as has been observed previously in the S(2) state [Boussac, A., Un, S., Horner, O., and Rutherford, A. W. (1998) Biochemistry 37, 4001-4007]. Illumination of the S(3) state with near-infrared light (700-900 nm), at temperatures around 50 K, results in the modification of the low-field signals and most notably to the appearance of a broad (DeltaH approximately 200 G) radical-type signal centered at g = 2. The signal is tentatively assigned to the interaction of the Mn cluster in a modified S(2) state with a radical.

Influence of fulvic acid on the collagen secretion of bovine chondrocytes in vitro.

High concentrations of fulvic acid and selenium deficiency in drinking water are the main causative factors of Kashin-Beck disease, an endemic degenerative chronic osteoarticular disorder found in China. The influence of fulvic acid on collagen secretion was investigated in articular chondrocyte cultures from bovine interphalangeal joints. Collagen secretion in 7-day-old chondrocyte monolayers was determined by measuring [3H]-proline incorporation into collagen macromolecules after a 24-h application in cultured supernatants. Additionally, collagen secretion was measured with a collagen assay based on a dye-binding method of soluble collagens. Both methods showed a dose-dependent increase of collagen secretion after treatment with fulvic acid. The collagen was identified by immunoblotting and immunocytochemistry as type II collagen. Fulvic acid also induced H2O2 production in cartilage cells. After co-incubation with catalase and fulvic acid, the cells secreted the same amount of H2O2 or collagen as the non-treated controls, indicating an influence of H2O2 on collagen secretion. Chondrocytes were then treated directly with H2O2. This led to increased collagen secretion showing a positive correlation with the concentration of H2O2 up to 1 pM H2O2. Larger amounts of H2O2 decreased collagen secretion. Effects of reactive oxygen species, such as lipid peroxidation or lactate dehydrogenase (LDH) release from damaged cells, were not inducable by fulvic acid (<10 ppm). Our results demonstrate a fulvic-acid-induced stimulation of collagen secretion into the supernatant by articular chondrocytes via physiological amounts of H2O2.

NO reversibly reduces the water-oxidizing complex of photosystem II through S0 and S-1 to the state characterized by the Mn(II)-Mn(III) multiline EPR signal.

Incubation of photosystem II preparations with NO at -30 degreesC results in the slow formation of a unique state of the water-oxidizing complex (WOC), which was recently identified as a Mn(II)-Mn(III) dimer [Sarrou, J., Ioannidis, N., Deligiannakis, Y., and Petrouleas, V. (1998) Biochemistry 37, 3581-3587]. Evolution of the Mn(II)-Mn(III) EPR signal proceeds through one or more intermediates [Goussias, C., Ioannidis, N., and Petrouleas, V. (1997) Biochemistry 36, 9261-9266]. In an effort to identify these intermediates, we have examined the time course of the signal evolution in the presence and absence of methanol. An early step of the interaction of NO with the WOC is the reduction of S1 to the S0 state, characterized by the weak Mn-hyperfine structure recently reported for that state. At longer times S0 is further reduced to a state which has the properties of the S-1 state, in that single-turnover illumination restores the S0 signal. The Mn(II)-Mn(III) state forms after the S-1 state and is tentatively assigned to an (iso)S-2 state, although lower states or a modified S-1 state cannot be excluded at present. Following removal of NO 60-65% of the initial S2 multiline signal size or the O2-evolving activity can be restored. The data provide for the first time EPR information on a state lower than S0. Furthermore, the low-temperature NO treatment provides a simple means for the selective population of the S0, S-1 and the Mn(II)-Mn(III) states.

Response of the NAD(P)H-oxidising flavohaemoglobin (Hmp) to prolonged oxidative stress and implications for its physiological role in Escherichia coli.

The Escherichia coli flavohaemoglobin (Hmp) has a globin-like N-terminal domain and a ferredoxin-NADP-reductase-like C-terminal domain. We show here that purified Hmp oxidises both NADH and NADPH with Km values of 1.8 and 19.6 microM, respectively. Prolonged incubation of a hmp-lacZ fusion strain with the redox cycling agent paraquat resulted in a 28-fold induction of hmp gene expression, nearly 3-fold higher than after short periods of exposure. A strain overproducing Hmp was significantly more sensitive to paraquat than was the wild-type strain but, in vitro, purified Hmp was not an effective NADPH-paraquat diaphorase. Prolonged incubation of a wild-type strain with paraquat increased intracellular Hmp to spectrally detectable levels.

Lipidosis induced in rat uteri by high doses of tamoxifen.

The anti-estrogenic drug tamoxifen is an amphiphilic cationic compound and might therefore be expected to interfere with intralysosomal catabolism of polar lipids as has been previously reported with several other amphiphilic cationic drugs. The purpose of this study was to investigate whether there is lipidosis induction in the uterus. High oral doses of tamoxifen (100 mg/kg) were administered to 9 adult rats for 6-14 weeks. Their uteri were examined by light and electron microscopy. Lipidosis-like alterations were seen in the glandular epithelia and in the myometrium. The luminal epithelium was most severely affected. The highest degree of intraepithelial change was already observed after a short-term treatment (6 weeks). The results support the previously proposed concept of a relationship between the amphiphilic cationic character of a compound and its ability to cause intralysosomal storage of polar lipids after a high dosage treatment of these drugs in animals.

A Mn(II)-Mn(III) EPR signal arises from the interaction of NO with the S1 state of the water-oxidizing complex of photosystem II.

It was shown recently [Goussias, C., Ioannidis, N., and Petrouleas, V. (1997) Biochemistry 36, 9261-9266] that incubation of photosystem II preparations with NO at -30 degrees C in the dark results in the formation of a new intermediate of the water-oxidizing complex. This is characterized by an EPR signal centered at g = 2 with prominent manganese hyperfine structure. We have examined the detailed structure of the signal using difference EPR spectroscopy. This is facilitated by the observations that NO can be completely removed without decrease or modification of the signal, and illumination at 0 degree C eliminates the signal. The signal spans 1600 G and is characterized by sharp hyperfine structure. 14NO and 15NO cw EPR combined with pulsed ENDOR and ESEEM studies show no detectable contributions of the nitrogen nucleus to the spectrum. The spectrum bears similarities to the experimental spectrum of the Mn(II)-Mn(III) catalase [Zheng, M., Khangulov, S. V., Dismukes, G. C., and Barynin, V. V. (1994) Inorg. Chem. 33, 382-387]. Simulations allowing small variations in the catalase-tensor values result in an almost accurate reproduction of the NO-induced signal. This presents strong evidence for the assignment of the latter to a magnetically isolated Mn(II)-Mn(III) dimer. Since the starting oxidation states of Mn are higher than II, we deduce that NO acts effectively as a reductant, e.g., Mn(III)-Mn(III) + NO--> Mn(II)-Mn(III) + NO+. The temperature dependence of the nonsaturated EPR-signal intensity in the range 2-20 K indicates that the signal results from a ground state. The cw microwave power saturation data in the range 4-8 K can be interpreted assuming an Orbach relaxation mechanism with an excited state at delta = 42 K. Assuming antiferromagnetic coupling, -2JS1.S2, between the two manganese ions, J is estimated to be 10 cm-1. The finding that an EPR signal from the Mn cluster of PSII can be clearly assigned to a magnetically isolated Mn(II)-Mn(III) dimer bears important consequences in interpreting the structure of the Mn cluster. Although the signal is not currently assigned to a particular S state, it arises from a state lower than S1, possibly lower than S0, too.

Low-temperature interactions of NO with the S1 and S2 states of the water-oxidizing complex of photosystem II. A novel Mn-multiline EPR signal derived from the S1 state.

The spin-1/2-carrying NO molecule interacts with both the S1 and S2 states of the water oxidizing complex. The intermediates of the interaction can be resolved and trapped by NO treatment at subzero temperatures. At -30 degrees C and in the presence of approx. 500-700 microM NO, S1 loses the ability to yield by illumination an EPR active S2-state with an approximate half-time of 40-60 min. At longer incubation times (t1/2 = 4-5 h), an intense new multiline signal develops. The new signal has a hyperfine splitting similar to the S2 multiline [Dismukes, G. C., & Siderer, Y. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 274-278], but a modified shape with intense lines on the high field side. The NO modified S1 state can act as a low-temperature electron donor yielding an EPR silent state upon illumination at 200 K. NO interacts also with the S2 state of the water oxidizing complex rapidly at temperatures as low as -75 degrees C, to yield an EPR silent state. The rates of the latter interaction show analogies to the ammonia binding to the S2 state. It is possible, however, that NO, unlike ammonia, destabilizes the S2 state. On the basis of preliminary experiments with varying chloride concentrations in the range 0.1-50 mM, the S1 multiline state is attributed to binding of NO at a chloride sensitive site on the Mn cluster. The rapid interactions with the S2 state as well as the intermediate binding to the S1 state are less well understood at present, but they are tentatively assigned to the chloride-insensitive site of ammonia binding in the Mn cluster.

The flavohaemoglobin (HMP) of Escherichia coli generates superoxide in vitro and causes oxidative stress in vivo.

Purified flavohaemoglobin (HMP) of Escherichia coli reduces Fe(III) in a superoxide dismutase (SOD)-sensitive reaction, demonstrating superoxide anion generation during aerobic NADH oxidation. In vivo, sodA-lacZ fusion activity was increased 3-fold by introducing plasmid pPL341, containing the hmp gene, or by growth with paraquat. The effects were additive and SOXS-dependent. Thus HMP activity causes oxidative stress in vivo. Activities of sodA-lacZ and hmp-lacZ fusions were stimulated in a himA mutant, demonstrating repression of both promoters by integration host factor (IHF), but the effects of pPL341 on sodA-lacZ activity were not due to titration of IHF by the hmp promoter.

Reactions of the Escherichia coli flavohaemoglobin (Hmp) with oxygen and reduced nicotinamide adenine dinucleotide: evidence for oxygen switching of flavin oxidoreduction and a mechanism for oxygen sensing.

The soluble flavohaemoglobin (Hmp) of Escherichia coli contains haem B and FAD in a single 44 kDa polypeptide, and shows NADH oxidase activity. The oxidized protein reacted rapidly with NADH in the presence of O2 to form an oxygenated species while the flavin remained largely oxidized. Spectral and kinetic analyses revealed rapid biphasic reduction and oxygenation of high-spin haem with apparent relaxation times of 6 and 64 ms at pH 8 and 25 degrees c, suggestive of a significant physiological role for the protein. This was followed by a monophasic reduction of the flavin with a relaxation time of 92 ms. On exhaustion of oxygen, the oxygenated haem was converted into the deoxy form biphasically with relaxation times of 43 and 170 s, followed by extensive reduction of the flavin with corresponding relaxation times of 70 and 256 s. Based on these observations, we propose that Hmp could act as an oxygen sensor in E. coli by combining with intracellular oxygen, thus limiting flavin reduction in the aerobic steady state. Lowering of the oxygen concentration causes dissociation of the oxy species and sustained flavin reduction. Because Hmp can reduce Fe(III), such a mechanism might control, for example, flavin-mediated Fe(III) reduction required for activation of the anaerobic gene regulator, Fnr.