Environmental detection of SARS-CoV-2 in hospital rooms in different wards of a university hospital.

BACKGROUND: Transmission of severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) can occur through direct, indirect, or close contact with infected people. However, the extent of environmental contamination is unknown. The nature of the relation between patients' symptoms and SARS-CoV-2 environmental shedding remains unclear. The aim of this study was to assess the relationship between patient coronavirus disease 2019 (COVID-19) status and environmental contamination. METHODS: Between May and November 2020, environmental swabs were taken before and after room disinfection at day 7 after symptom onset in a cohort of patients clinically or biologically diagnosed with COVID-19. Twelve surfaces per room were collected in 13 rooms. Sample analysis was performed by reverse transcription polymerase chain reaction (RT-PCR) for SARS-CoV-2 detection [SARS-CoV-2 R-Gene (biomérieux, Marcy l'Etoile, France)]. Clinical data (day of illness, symptoms, RT-PCR results) was collected from the clinical software. RESULTS: Five medical units were included in the study. Of 156 samples collected in 13 rooms, five rooms (38.5%) presented 11 SARS-CoV-2-positive samples. These positive samples were detected on eight different surfaces. There was no association between detection of SARS-CoV-2 and patient age (P=1) or patient symptoms (P=0.3). CONCLUSION: Viral shedding during COVID-19 appears to be unrelated to the presence of symptoms, patient age, and low-value cycle threshold of patient's test. This study supports the evidence for the environmental shedding of SARS-CoV-2 until at least 7 days after symptom onset. It emphasizes the need for strict compliance with contact precautions, hand hygiene, the correct use of personal protective equipment and room disinfection for the routine care of patients with COVID-19.

Local probe investigation of electrocatalytic activity.

As the world energy crisis remains a long-term challenge, development and access to renewable energy sources are crucial for a sustainable modern society. Electrochemical energy conversion devices are a promising option for green energy supply, although the challenge associated with electrocatalysis have caused increasing complexity in the materials and systems, demanding further research and insights. In this field, scanning probe microscopy (SPM) represents a specific source of knowledge and understanding. Thus, our aim is to present recent findings on electrocatalysts for electrolysers and fuel cells, acquired mainly through scanning electrochemical microscopy (SECM) and other related scanning probe techniques. This review begins with an introduction to the principles of several SPM techniques and then proceeds to the research done on various energy-related reactions, by emphasizing the progress on non-noble electrocatalytic materials.

Monthly reference change value of cardiac troponin in hemodialysis patients as a useful tool for long-term cardiovascular management.

PURPOSE OF RESEARCH: Circulating cardiac troponin (cTn) has been identified as a risk factor for cardiovascular and overall mortality in patients undergoing hemodialysis. However, its interpretation remains difficult due to the high prevalence of patients with cTn level beyond the 99th percentile. Determining the cTn reference change value (RCV) may help in assessing a clinically significant change of cTn during regular follow-up of patients. We aimed to determine the long-term RCV of cTn in such patients and to calculate the perdialytic reduction rate of cTn. DESIGN AND METHODS: To calculate RCV, high-sensitivity (hs)-cTnT (Roche), hs-cTnI (Abbott), and cTnI-ultra (Siemens) were determined every month before the midweek dialysis session over a 3-month period in 36 stable hemodialysis patients. cTn was also measured after the midweek dialysis session to calculate the cTn removal rate. RESULTS: The mean RCV (95% confidence interval) was 22% (18-26) for hs-cTnT versus 53% (34-73) for hs-cTnI versus 65% (45-84) for cTnI-ultra. Log-normal RCV (%) was -19/+25 for hs-cTnT, -33/+96 for hs-cTnI, and -39/+115 for cTnI-ultra. The index of individuality was <0.6 regardless of the cTn assay used. A significantly greater reduction rate was observed for hs-cTnT (48%) than for hs-cTnI (30%, p<0.001) and cTnI-ultra (29%, p<0.05). CONCLUSIONS: These results underline the need to use the RCV approach rather than cutoff points to identify the critical change in long-term serial cTn levels. In addition, RCV should be determined for each available assay due to significant differences between assays. Removal of cTn during hemodialysis sessions should also be considered if acute coronary syndrome is suspected during a session.

Phenolic metabolism in petunia tissues. I. Characteristic responses of enzymes involved in different steps of polyphenol synthesis to different hormonal influences.

Pronounced changes in enzymatic patterns occur in petunia tissues when calluses are subcultured on media containing different growth substances. As judged by variations of enzymes related to primary metabolism (6-phosphogluconate and malate dehydrogenases) there are individual responses for each metabolic pathway. Concerning the enzymes of aromatic metabolism: (a) Phenylalanine ammonia-lyase, cinnamate and p-coumarate hydroxylases and the enzyme(s) activating phenylpropanoid units vary in the same manner. (b) Chalcone-flavanone isomerase, a key enzyme in the synthesis of flavonoids, and coniferyl alcohol dehydrogenase, which leads to the monomers of lignins, have, on the other hand, an independent behaviour. These responses show that the enzymes involved in the synthesis and activation of phenylpropanoid units seem to act coordinately in plants. Moreover, the data suggest that the common pathway leading to the activated cinnamic acids and the specific metabolic steps of lignin and flavonoid synthesis are regulated in a different way.

A molecular model for cinnamyl alcohol dehydrogenase, a plant aromatic alcohol dehydrogenase involved in lignification.

The plant aromatic alcohol dehydrogenase, cinnamyl alcohol dehydrogenase (CAD2 from Eucalyptus) was found by sequence analysis of its cloned gene to be homologous to a range of dehydrogenases including alcohol dehydrogenases, L-threonine-3-dehydrogenase, D-xylose reductase and sorbitol dehydrogenase. A homology model of CAD2 was built using the X-ray crystallographic coordinates of horse-liver alcohol dehydrogenase to provide the template, with additional modelling input from other analogous regions of structure from similar enzymes where necessary. The structural model thus produced rationalised the Zn-binding properties of CAD2, indicated the possession of a Rossmann fold (GXGXXG motif), and explained the class A stereospecificity (pro-R hydrogen removal from substrate alcohol) and aromatic substrate specificity of the enzyme. A range of potential ligands was designed based on the homology model and tested as inhibitors of CAD2 and horse liver alcohol dehydrogenase.

Purification and Characterization of Cinnamyl Alcohol Dehydrogenase Isoforms from the Periderm of Eucalyptus gunnii Hook.

Cinnamyl alcohol dehydrogenase (CAD, EC 1.1.1.195) isoforms were purified from the periderm (containing both suberized and lignified cell layers) of Eucalyptus gunnii Hook stems. Two isoforms (CAD 1P and CAD 2P) were initially characterized, and the major form, CAD 2P, was resolved into three further isoforms by ion-exchange chromatography. Crude extracts contained two aliphatic alcohol dehydrogenases (ADH) and one aromatic ADH, which was later resolved into two further isoforms. Aliphatic ADHs did not use hydroxycinnamyl alcohols as substrates, whereas both aromatic ADH isoforms used coniferyl and sinapyl alcohol as substrates but with a much lower specific activity when compared with benzyl alcohol. The minor form, CAD 1P, was a monomer with a molecular weight of 34,000 that did not co-elute with either aromatic or aliphatic ADH activity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and western blot analysis demonstrated that this protein was very similar to another CAD isoform purified from Eucalyptus xylem tissue. CAD 2P had a native molecular weight of approximately 84,000 and was a dimer consisting of two heterogenous subunits (with molecular weights of 42,000 and 44,000). These subunits were differentially combined to give the heterodimer and two homodimers. SDS-PAGE, western blots, and nondenaturing PAGE indicated that the CAD 2P heterodimer was very similar to the main CAD isoform previously purified in our laboratory from differentiating xylem tissue of E. gunnii (D. Goffner, I. Joffroy, J. Grima-Pettenati, C. Halpin, M.E. Knight, W. Schuch, A.M. Boudet [1992] Planta 188: 48-53). Kinetic data indicated that the different CAD 2P isoforms may be implicated in the preferential production of different monolignols used in the synthesis of lignin and/or suberin.

Purification and Characterization of Cinnamoyl-Coenzyme A:NADP Oxidoreductase in Eucalyptus gunnii.

Cinnamoyl-coenzyme A:NADP oxidoreductase (CCR, EC 1.2.1.44), the entry-point enzyme into the monolignol biosynthetic pathway, was purified to apparent electrophoretic homogeneity from differentiating xylem of Eucalyptus gunnii Hook. The purified protein is a monomer of 38 kD and has an isoelectric point of 7. Although Eucalyptus gunnii CCR has approximately equal affinities for all possible substrates (p-coumaroyl-coenzyme A, feruloyl-coenzyme A, and sinapoyl-coenzyme A), it is approximately three times more effective at converting feruloyl-coenzyme A than the other substrates. To gain a better understanding of the catalytic regulation of Eucalyptus CCR, a variety of compounds were tested to determine their effect on CCR activity. CCR activity is inhibited by NADP and coenzyme A. Effectors that bind lysine and cysteine residues also inhibit CCR activity. As a prerequisite to the study of the regulation of CCR at the molecular level, polyclonal antibodies were obtained.

Cinnamyl Alcohol Dehydrogenase: Identification of New Sites of Promoter Activity in Transgenic Poplar.

Stem sections from poplar that were stably transformed with a eucalypt cinnamyl alcohol dehydrogenase promoter-[beta]-glucuronidase construct were prepared by using either a technique routinely used in herbaceous species or a technique designed to take into account the particular anatomy of woody plants. Although both preparation techniques confirmed the pattern of expression previously observed (C. Feuillet, V. Lauvergeat, C. Deswarte, G. Pilate, A. Boudet and J. Grima-Pettenati [1995] Plant Mol Biol 27: 651-657), the latter technique also allowed the detection of other sites of promoter activity not revealed by the first technique. In situ hybridization confirmed the expression pattern obtained with the second sample preparation technique.

Enrichment in Specific Soluble Sugars of Two Eucalyptus Cell-Suspension Cultures by Various Treatments Enhances Their Frost Tolerance via a Noncolligative Mechanism.

A cell-suspension culture obtained from the hybrid Eucalyptus gunnii/Eucalyptus globulus was hardened by exposure to lower temperatures, whereas in the same conditions cells from a hybrid with a more frost-sensitive genotype, Eucalyptus cypellocarpa/Eucalyptus globulus, were not able to acclimate. During the cold exposure the resistant cells accumulated soluble sugars, in particular fructose and sucrose, with a limited increase in cell osmolality. In contrast, the cell suspension that was unable to acclimate did not accumulate soluble sugars in response to the same cold treatment. To an extent similar to that induced after a cold acclimation, frost-hardiness of the cells increased after a 14-h incubation with specific soluble sugars such as sucrose, raffinose, fructose, and mannitol. Such hardening was also observed for long-term cultures in mannitol-enriched medium. This cryoprotective effect of sugars without exposure to lower temperatures was observed in both the resistant and the sensitive genotypes. Mannitol was one of the most efficient carbohydrates for the cryoprotection of eucalyptus. The best hardiness (a 2.7-fold increase in relative freezing tolerance) was obtained for the resistant cells by the cumulative effect of cold-induced acclimation and mannitol treatment. This positive effect of certain sugars on eucalyptus freezing tolerance was not colligative, since it was independent of osmolality and total sugar content.

Phenolic metabolism in petunia tissues. IV. - Properties of p-coumarate : coenzyme A ligase isoenzymes.

Three p-coumarate: CoA ligases were separated from Petunia leaves. There was no interconversion from one form to another. The isoenzymes had a number of common properties: optimum pH, instability in the absence of polyols, action on p-coumaric acid as the common substrate. These enzymes differed significantly with respect to: --their substrate specificity towards the other C6-C3 units of Petunia. Form Ia (caffeate: CoA ligase) acted on caffeic acid, form Ib (sinapate: CoA ligase) on sinapic acid form II (ferulate: CoA ligase) on ferulic acid. --their thermal stability. --their sensitivity to phenolics: (a) caffeate: CoA ligase was inhibited by p-coumaroyl and caffeoyl quinic esters. It was insensitive to p-coumaroyl-glucose, on one hand and to a number of flavonoids on the other. (b) ferulate: CoA ligase was specifically inhibited by naringenin. (c) sinapate: CoA ligase was not inhibited by the selected compounds. In all cases, the inhibition was of the non competitive type and the enzymes were desensized to the modifier action by thermal treatment independently from the enzyme activity. These results suggest the occurrence of distinct sites of reception for the substrate and the inhibitor on the enzyme molecule. All these data are consistent with the hypothesis of the possible participation of each individual form in a limited number of pathways. This would be of physiological interest since the metabolic fate of the different cinnamic acids could be independently controlled at the p-coumarate: CoA ligase level.

Evidence for the involvement of activated oxygen in fungal degradation of lignocellulose.

Oxygen has been shown to be necessary as a cosubstrate for the fungal degradation of lignins. In this work, the active forms of oxygen were tentatively identified in three ways: --effect of chemically generated active radicals and molecular species on lignocellulosic complexes, --use of activated oxygen scavengers in culture media of ligninolytic fungi, --characterization of active forms of oxygen by specific reactions. The data obtained strongly suggest that two main oxygen species are involved, namely OH radical and singlet oxygen (1O2). Chemical or enzymic scavengers inhibit the degradation of lignocelluloses by Phanerochaete chrysosporium. The fungus has been demonstrated to synthesize OH.

Biochemistry and molecular biology of lignification.

Lignins, which result from the dehydrogenative polymerization of cinnamyl alcohols, are complex heteropolymers deposited in the walls of specific cells of higher plants. Lignins have probably been associated to land colonization by plants but several aspects concerning their biosynthesis, structure and function are still only partially understood. This review focuses on the modern physicochemical methods of structural analysis of lignins, and on the new approaches of molecular biology and genetic engineering applied to lignification. The principles, advantages and limitations of three important analytical tools for studying lignin structure are presented. They include carbon 13 nuclear magnetic resonance, analytical pyrolysis and thioacidolysis. The use of these methods is illustrated by several examples concerning the characterization of grass lignins,'lignin-like'materials in protection barriers of plants and lignins produced by cell suspension cultures. Our present limited knowledge of the spatio temporal deposition of lignins during cell wall differentiation including the nature of the wall components associated to lignin deposition and of the cross-links between the different wall polymers is briefly reviewed. Emphasis is placed on the phenylpropanoid pathway enzymes and their corresponding genes which are described in relation to their potential roles in the quantitative and qualitative control of lignification. Recent findings concerning the promoter sequence elements responsible for the vascular expression of some of these genes are presented. A section is devoted to the enzymes specifically involved in the synthesis of monolignols: cinnamoyl CoA reductase and cinnamyl alcohol dehydrogenase. The recent characterization of the corresponding cDNAs/genes offers new possibilities for a better understanding of the regulation of lignification. Finally, at the level of the synthesis, the potential involvement of peroxidases and laccases in the polymerization of monolignols is critically discussed. In addition to previously characterized naturally occurring lignin mutants, induced lignin mutants have been obtained during the last years through genetic engineering. Some examples include plants transformed by O-methyltransferase and cinnamyl alcohol dehydrogenase antisense constructs which exhibit modified lignins. Such strategies offer promising perspectives in gaining a better understanding of lignin metabolism and functions and represent a realistic way to improve plant biomass. Contents Summary 203 I. Introduction 204 II. Main structural features of lignins 205 III. Lignification and cell wall differentiation: spatio-temporal deposition of lignins and inter-relations with other wall components 213 IV. Enzymes and genes involved in the biosynthesis and polymerization of monolignols 216 V. Lignin mutants as a way to improve plant biomass and to explore lignin biochemistry and metabolism 226 VI. Concluding remarks 229 Acknowledgements 230 References 230.

Cross-coupling of hydroxycinnamyl aldehydes into lignins.

Pathways for hydroxycinnamyl aldehyde incorporation into lignins are revealed by examining transgenic plants deficient in cinnamyl alcohol dehydrogenase, the enzyme that converts hydroxycinnamyl aldehydes to the hydroxycinnamyl alcohol lignin monomers. In such plants the aldehydes incorporate into lignins via radical coupling reactions. As diagnostically revealed by long-range (13)C-(1)H correlative NMR, sinapyl aldehyde (3, 5-dimethoxy-4-hydroxy-cinnamaldehyde) 8-O-4-cross-couples with both guaiacyl (3-methoxy-4-hydroxyphenyl-propanoid) and syringyl (3, 5-dimethoxy-4-hydroxyphenyl-propanoid) units, whereas coniferyl aldehyde cross-couples only with syringyl units.

Purification and characterization of cinnamyl alcohol dehydrogenase isoforms from Phaseolus vulgaris.

Cinnamyl alcohol dehydrogenase (CAD) catalyses the reduction of hydroxycinnamaldehydes (p-coumaryl, coniferyl, sinapyl) to the corresponding alcohols which are the monomeric precursors of lignins. We have demonstrated the occurrence of two isoforms of CAD (CAD1 and CAD2) in bean which differ in terms of subunit Mr, specific activity, substrate affinity and antigenicity. The most abundant polypeptide in bean pods, organs with very limited lignification, is a low affinity CAD isoform (CAD1). This enzyme which is distinct from a benzyl alcohol dehydrogenase with broad substrate specificity, was purified to apparent homogeneity and partial amino acid sequencing was carried out using internal peptides obtained by trypsin cleavage.

Reassessment of qualitative changes in lignification of transgenic tobacco plants and their impact on cell wall assembly.

In tobacco plants the effect of antisense down-regulation of various genes encoding enzymes of the monolignol biosynthetic pathway resulted in quantitative and qualitative changes in lignin distribution and in diverse alterations of the secondary wall assembly of modified tobacco plants. Total lignin content, composition in syringyl and guaiacyl units, and absolute proportions of condensed and non-condensed substructures occurring in the cell walls, were differentially modified according to the repressed gene. Immunocytochemical characterisation and visualisation of the distribution of condensed and non-condensed lignin substructure epitopes in transmission electron microscopy (TEM) revealed that some transformations entailed profound and specific alterations in the secondary wall biogenesis. Correlation between micro-morphological cell wall alterations and semi-quantitative immuno-analysis of the topochemical distribution of lignin sub-units suggests that the mode of polymerisation of monolignols into non-condensed units, favoured by the microfibril matrix of the secondary wall, plays an important part in the lignified cell wall assembly.

Elucidation of new structures in lignins of CAD- and COMT-deficient plants by NMR.

Studying lignin-biosynthetic-pathway mutants and transgenics provides insights into plant responses to perturbations of the lignification system, and enhances our understanding of normal lignification. When enzymes late in the pathway are downregulated, significant changes in the composition and structure of lignin may result. NMR spectroscopy provides powerful diagnostic tools for elucidating structures in the difficult lignin polymer, hinting at the chemical and biochemical changes that have occurred. COMT (caffeic acid O-methyl transferase) downregulation in poplar results in the incorporation of 5-hydroxyconiferyl alcohol into lignins via typical radical coupling reactions, but post-coupling quinone methide internal trapping reactions produce novel benzodioxane units in the lignin. CAD (cinnamyl alcohol dehydrogenase) downregulation results in the incorporation of the hydroxycinnamyl aldehyde monolignol precursors intimately into the polymer. Sinapyl aldehyde cross-couples 8-O-4 with both guaiacyl and syringyl units in the growing polymer, whereas coniferyl aldehyde cross-couples 8-O-4 only with syringyl units, reflecting simple chemical cross-coupling propensities. The incorporation of hydroxycinnamyl aldehyde and 5-hydroxyconiferyl alcohol monomers indicates that these monolignol intermediates are secreted to the cell wall for lignification. The recognition that novel units can incorporate into lignins portends significantly expanded opportunities for engineering the composition and consequent properties of lignin for improved utilization of valuable plant resources.

A comparative study of two isoforms of laccase secreted by the "white-rot" fungus Rigidoporus lignosus, exhibiting significant structural and functional differences.

Two isoforms of laccase were obtained as the predominant phenol-oxidases in defined medium liquid cultures of the "white-rot" fungus Rigidoporus lignosus (R. lignosus). A characterization of the two laccases was made in terms of molecular mass, isoelectric point, metal content and N-terminal sequence. Furthermore, in order to gain information on the structural features related to the metal centers, a study of their geometric arrangement and their redox ability was made. It turned out that the two isoenzymes greatly differed with regard to pH stability, catalytic and copper centers features. It is proposed that all such differences are dependent on the amino acid sequences, which cause a distortion of the copper sites, thus accounting for the redox potential values and kinetic properties.

Glassy cholesteric structure: thickness variation induced by electron radiation in transmission electron microscopy investigated by atomic force microscopy.

During the observation of glassy cholesteric liquid crystals in transmission electron microscopy (TEM), a new contrast is created or enhanced by electron radiation which has a direct relationship with the periodic microstructure of the specimen. In this paper, we investigate the variations of the sample thickness and mass density as possible causes of this irradiation contrast. By means of observations in atomic force microscopy (AFM) coupled to TEM, we compared the surface corrugations of non-irradiated and irradiated specimens. It is shown that the final contrast is the result of several processes. including fracture during ultramicrotomy and mass loss during irradiation. Mass loss acts as an etching, and hence results in a decrease of the sample thickness. The etching depends on the initial molecular orientation, thus evidencing the latent structure. An electron channelling mechanism is suggested to explain this behaviour.

Complexes of Al(III) with 3'4'-dihydroxy-flavone: characterization, theoretical and spectroscopic study.

Complex formation between aluminium chloride and 3'4'-dihydroxyflavone (3'4'diOHF) in methanol has been studied by UV-visible and Raman spectroscopies combined with quantum chemical calculations. Job's method of continuous variation and the molar ratio method were applied to ascertain the stoichiometry composition of the chelate in pure methanol. A 1:1 complex was indicated by both the methods. Geometry optimizations of free and complexed molecules by AMI and DFT methods show that structural modifications of the ligand, induced by complexation, are minor, and are localized on the chelating site. The good agreement between experimental and theoretical electronic spectra of both 3'4'diOHF and complex confirm the structural models. The great similarities between Raman spectra of the free and complexed form constitute an another proof of the absence of pronounced electronic and geometric changes, and notably demonstrate that the quinoidal form induced by the deprotonation of the two hydroxyl groups does not participate in the 3'4'diOHF complex structure. Whereas no complexation occurs in acidic medium, complexes of high stoichiometry are formed in alkaline medium. (Al(3'4'diOHF)2)- and (Al(3'4'diOHF)3)3- species are observed in methanol in the presence of sodium acetate or sodium methanoate.

Conformational and spectroscopic investigation of 3-hydroxyflavone-aluminium chelates.

3-Hydroxyflavone (3HF), which is the simplest molecule of the flavonol class, possesses chelating properties towards Al(III). Spectrophotometric methods have shown that the 3HF molecule forms an Al(3HF)2 complex in pure methanol. The structure of this complex, obtained by quantum semi-empirical AM1 method, indicated that complexed 3HF adopts a pyronium form. Structural and electronic modifications induced by chelation are illustrated by the important frequency shifts observed between free and complexed 3HF FT-Raman spectra and by the chemical shifts variations in the 13C NMR spectra of the two species. Complexes with the same stoichiometry were formed when AcO- or MeO- are present in the medium. However, in acidic medium the chelate composition is Al2(3HF).