The source of inorganic nitrogen has distinct effects on cell wall composition in Brachypodium distachyon.

Plants have evolved different strategies to utilize various forms of nitrogen (N) from the environment. While regulation of plant growth and development in response to application of inorganic N forms has been characterized, our knowledge about the effect on cell wall structure and composition is quite limited. In this study, we analysed cell walls of Brachypodium distachyon supplied with three types of inorganic N (NH4NO3, NO3-, or NH4+). Cell wall profiles showed distinct alterations in both the quantity and structures of individual polymers. Nitrate stimulated cellulose, but inhibited lignin deposition at the heading growth stage. On the other hand, ammonium supply resulted in higher concentration of mixed linkage glucans. In addition, the chemical structure of pectins and hemicelluloses was strongly influenced by the form of N. Supply of only NO3- led to alteration in xylan substitution and to lower esterification of homogalacturonan. We conclude that the physiological response to absorption of different inorganic N forms includes pleotropic remodelling of type II cell walls.

A comparative structural analysis of the surface properties of asco-laccases.

Laccases of different biological origins have been widely investigated and these studies have elucidated fundamentals of the generic catalytic mechanism. However, other features such as surface properties and residues located away from the catalytic centres may also have impact on enzyme function. Here we present the crystal structure of laccase from Myceliophthora thermophila (MtL) to a resolution of 1.62 Å together with a thorough structural comparison with other members of the CAZy family AA1_3 that comprises fungal laccases from ascomycetes. The recombinant protein produced in A. oryzae has a molecular mass of 75 kDa, a pI of 4.2 and carries 13.5 kDa N-linked glycans. In the crystal, MtL forms a dimer with the phenolic substrate binding pocket blocked, suggesting that the active form of the enzyme is monomeric. Overall, the MtL structure conforms with the canonical fold of fungal laccases as well as the features specific for the asco-laccases. However, the structural comparisons also reveal significant variations within this taxonomic subgroup. Notable differences in the T1-Cu active site topology and polar motifs imply molecular evolution to serve different functional roles. Very few surface residues are conserved and it is noticeable that they encompass residues that interact with the N-glycans and/or are located at domain interfaces. The N-glycosylation sites are surprisingly conserved among asco-laccases and in most cases the glycan displays extensive interactions with the protein. In particular, the glycans at Asn88 and Asn210 appear to have evolved as an integral part of the asco-laccase structure. An uneven distribution of the carbohydrates around the enzyme give unique properties to a distinct part of the surface of the asco-laccases which may have implication for laccase function-in particular towards large substrates.

The impact of silicon on cell wall composition and enzymatic saccharification of Brachypodium distachyon.

BACKGROUND: Plants and in particular grasses benefit from a high uptake of silicon (Si) which improves their growth and productivity by alleviating adverse effects of biotic and abiotic stress. However, the silicon present in plant tissues may have a negative impact on the processing and degradation of lignocellulosic biomass. Solutions to reduce the silicon content either by biomass engineering or development of downstream separation methods are therefore targeted. Different cell wall components have been proposed to interact with the silica pool in plant shoots, but the understanding of the underlying processes is still limited. RESULTS: In the present study, we have characterized silicon deposition and cell wall composition in Brachypodium distachyon wild-type and low-silicon 1 (Bdlsi1-1) mutant plants. Our analyses included different organs and plant developmental stages. In the mutant defective in silicon uptake, low silicon availability favoured deposition of this element in the amorphous form or bound to cell wall polymers rather than as silicified structures. Several alterations in non-cellulosic polysaccharides and lignin were recorded in the mutant plants, indicating differences in the types of linkages and in the three-dimensional organization of the cell wall network. Enzymatic saccharification assays showed that straw from mutant plants was marginally more degradable following a 190 °C hydrothermal pretreatment, while there were no differences without or after a 120 °C hydrothermal pretreatment. CONCLUSIONS: We conclude that silicon affects the composition of plant cell walls, mostly by altering linkages of non-cellulosic polymers and lignin. The modifications of the cell wall network and the reduced silicon concentration appear to have little or no implications on biomass recalcitrance to enzymatic saccharification.

Proteolysis in pork loins during superchilling and regular chilling storage.

This study aimed to address the proteolytic phenomena taking place in pork loins during prolonged storage at superchilling (SC) temperature. Loins were stored at either chilling (CH) conditions (2-4 °C) for 4 weeks or at SC temperature (around -1 °C) for 12 weeks. Storage at SC temperatures slowed down the rate of proteolysis in pork loins, so that final levels of most indicators for proteolysis, including after 12 weeks of SC storage were similar to those after 4 weeks at CH conditions. Consequently, the texture of SC pork under extended storage was not so different to that of CH pork. However, total amino acid content peaked by the end of SC storage, pointing out to a potential ongoing exopeptidase activity. Overall, proteolysis seemed to be slowed down in pork at SC conditions, with similar levels for most indicators after 12 weeks of SC storage or 4 weeks at CH conditions.

High-throughput analysis of amino acids in plant materials by single quadrupole mass spectrometry.

BACKGROUND: The amino acid profile of plants is an important parameter in assessments of their growth potential, resource-use efficiency and/or quality as food and feed. Screening studies may involve large number of samples but the classical amino acid analysis is limited by the fact that it is very time consuming with typical chromatographic run times of 70 min or more. RESULTS: We have here developed a high-throughput method for analysis of amino acid profiles in plant materials. The method combines classical protein hydrolysis and derivatization with fast separation by UHPLC and detection by a single quadrupole (QDa) mass spectrometer. The chromatographic run time is reduced to 10 min and the precision, accuracy and sensitivity of the method are in line with other recent methods utilizing advanced and more expensive mass spectrometers. The sensitivity of the method is at least a factor 10 better than that of methods relying on detection by fluorescence or UV. It is possible to downscale sample size to 20 mg without compromising reproducibility, which makes the method ideal for analysis of very small sample amounts. CONCLUSION: The developed method allows high-throughput analysis of amino acid profiles in plant materials. The analysis is robust and accurate as well as compatible with both free amino acids and protein hydrolysates. The QDa detector offers high sensitivity and accuracy, while at the same time being relatively simple to operate and cheap to purchase, thus significantly reducing the overall analytical costs compared to methods based on more advanced mass spectrometers.

Phylogeny and structure of the cinnamyl alcohol dehydrogenase gene family in Brachypodium distachyon.

Cinnamyl alcohol dehydrogenase (CAD) catalyses the final step of the monolignol biosynthesis, the conversion of cinnamyl aldehydes to alcohols, using NADPH as a cofactor. Seven members of the CAD gene family were identified in the genome of Brachypodium distachyon and five of these were isolated and cloned from genomic DNA. Semi-quantitative reverse-transcription PCR revealed differential expression of the cloned genes, with BdCAD5 being expressed in all tissues and highest in root and stem while BdCAD3 was only expressed in stem and spikes. A phylogenetic analysis of CAD-like proteins placed BdCAD5 on the same branch as bona fide CAD proteins from maize (ZmCAD2), rice (OsCAD2), sorghum (SbCAD2) and Arabidopsis (AtCAD4, 5). The predicted three-dimensional structures of both BdCAD3 and BdCAD5 resemble that of AtCAD5. However, the amino-acid residues in the substrate-binding domains of BdCAD3 and BdCAD5 are distributed symmetrically and BdCAD3 is similar to that of poplar sinapyl alcohol dehydrogenase (PotSAD). BdCAD3 and BdCAD5 expressed and purified from Escherichia coli both showed a temperature optimum of about 50 °C and molar weight of 49 kDa. The optimal pH for the reduction of coniferyl aldehyde were pH 5.2 and 6.2 and the pH for the oxidation of coniferyl alcohol were pH 8 and 9.5, for BdCAD3 and BdCAD5 respectively. Kinetic parameters for conversion of coniferyl aldehyde and coniferyl alcohol showed that BdCAD5 was clearly the most efficient enzyme of the two. These data suggest that BdCAD5 is the main CAD enzyme for lignin biosynthesis and that BdCAD3 has a different role in Brachypodium. All CAD enzymes are cytosolic except for BdCAD4, which has a putative chloroplast signal peptide adding to the diversity of CAD functions.

The reversible depletion and reconstitution of a copper ion in Coprinus cinereus laccase followed by spectroscopic techniques.

The specific activities of crude and purified Coprinus cinereus laccase preparations could be enhanced by a factor of 10-12 by activation with copper ions. The copper to protein contents of purified non-activated laccase were 2.3+/-0.1 compared to 3.3+/-0.1 in purified activated laccase indicating that only a fraction of the laccase can be activated. Purified laccase not activated with copper ions shows in isoelectric focusing four bands in order of decreasing pI in a ratio 1/5/3/1 where only bands I and II had laccase activity. Purified activated laccase showed only three bands (I, II and III) in the ratio 5/4/1 all with some laccase activity. The pH profile of the activity for activated and non-activated laccase showed identical behavior indicating that the active forms were the same. The change in UV-Vis around 330 nm following the depletion and reconstitution of the enzyme combined with activity measurements supports the reversibility of the selective removal and insertion of copper ions at the type 2 site. The circular dichroism spectrum of activated purified laccase has characteristic changes around 350 nm relative to non-activated laccase indicative of changes at the type 2/type 3 sites. The difference between the electron paramagnetic resonance spectra of non-activated and activated C. cinereus laccase indicates that a fraction of the non-activated purified laccase contained a copper(II) signal with a coupling constant between a type 1 and a type 2 copper(II). This electron paramagnetic resonance signal could be explained by an induced asymmetry in the type 3 site due to a missing type 2 copper ion.

Kinetic and theoretical comprehension of diverse rate laws and reactivity gaps in Coriolus hirsutus laccase-catalyzed oxidation of acido and cyclometalated Ru(II) complexes.

The reactivity of the acido Ru(II) complexes cis-[RuCl(2)(LL)(2)], [RuCO(3)(LL)(2)], cis-[RuCO(3)-(bquin)(2)] (LL = 2,2'-bipyridine (bpy) and 1,10-phenanthroline (phen); bquin = 2,2'-biquinoline) and cyclometalated Ru(II) derivatives of 2-phenylpyridine and 4-(2-tolyl)pyridine [Ru(o-C(6)H(4)-2-py)(phen)(2)]PF(6) (1), [Ru(o-C(6)H(3)-p-R-2-py)(bpy)(MeCN)(2)]PF(6) (2), and [Ru(o-C(6)H(3)-p-R-2-py)(phen)(MeCN)(2)]PF(6) (3) (R = H (a), Me (b)) toward laccase from Coriolus hirsutus has been investigated by conventional UV-vis spectroscopy at pH 3-7 and 25 degrees C. The acido and cyclometalated complexes are readily oxidized into the corresponding Ru(III) species, but the two types of complexes differ substantially in reactivity and obey different rate laws. The acido complexes are oxidized more slowly and the second-order kinetics, first-order in laccase and Ru(II), holds with the rate constants around 5 x 10(4) M(-1) s(-1) at pH 4.5 and 25 degrees C. The cyclometalated complexes 1-3 react much faster and the hyperbolic Michaelis-Menten kinetics holds. However, it is not due to formation of an enzyme-substrate complex but rather because of the ping-pong mechanism of catalysis, viz. E(ox) + Ru(II) --> E(red) + Ru(III) (k(1)); E(red) + 1/4O(2) --> E(ox) (k(2)), with the rate constants k(1) in the range (2-9) x 10(7) M(-1) s(-1) under the same conditions. The huge values of k(1) move the enzymatic oxidation toward a kinetic regime when the dioxygen half-reaction becomes the rate-limiting step. Cyclometalated compounds 1-3 can therefore be used for routine estimation of k(2), that is, the rate constant for reoxidation for laccases by dioxygen. The mechanism proposed was confirmed by the direct stopped-flow measurements of the k(2) rate constant (8.1 x 10(5) M(-1) s(-1) at 26 degrees C) and supported by the theoretical modeling of interaction between the bpy analogue of 1 and Coriolus hirsutes laccase using Monte Carlo simulations.

Kinetic studies on the reaction between Trametes villosa laccase and dioxygen.

A laccase from the fungus Trametes villosa (TviL) was investigated in order to elucidate the reaction mechanism of the reduction of dioxygen to water performed by this blue multi-copper oxidase. The ability of TviL to activate dioxygen was studied by stopped-flow experiments and under steady-state conditions. In the stopped-flow experiments TviL was reduced with a small excess of 4-hydroxyphenylacetic acid and afterwards the re-oxidation process was monitored by stopped-flow techniques by mixing with excess dioxygen. The reaction between reduced TviL and dioxygen was studied in the temperature range 10-35 degrees Celsius and with the concentration of dioxygen between 30 and 240microM. The observed rate constant k(obs) is found to be linear dependent on the dioxygen concentration and the observed second-order rate constant for the re-oxidation of reduced TviL is, at 25 degrees Celsius, determined to be 1.14x10(6)M(-1)s(-1). The activation energy, E(a), is from the same data determined to be 22kJmol(-1). Oxidation of different phenols (4-hydroxyphenylacetic acid, 4-hydroxybenzoic acid, guaiacolsulfonic acid and hydroquinone) under steady state conditions was investigated at concentrations of dioxygen ranging from 60 to 250microM. This line of experiments showed that TviL follows a ping-pong mechanism, and an observed second-order rate constant for the reaction with dioxygen of 7.1x10(5)M(-1)s(-1) at 25 degrees Celsius was found with 4-hydroxyphenylacetic acid as reducing substrate. The two kinetic methods resulted in observed rate constants of equal magnitudes for the reaction with dioxygen, which suggests that the rate limiting step(s) is (are) included in both the reactions studied by the two different techniques.