An Environmentally Friendly Nb–P–Si Solid Catalyst for Acid-Demanding Reactions

Here, we report the structural characteristics, the surface properties, and the catalytic performances of a Nb–P–Si ternary oxide material (2.5Nb2O5·2.5P2O5·95SiO2, 2.5NbP) in two reactions of importance for biomass valorisation and green industrial production: hydrolysis of inulin and esterification of oleic acid with polyalcohol for biolubricant production. High dispersion of the Nb centers, ascertained by UV–vis–DRS, 29Si, 31P, and 1H solid-state NMR spectroscopy, is the key point for the successful activity of 2.5NbP. Intrinsic and effective acidities of the sample were studied by FT-IR of adsorbed pyridine in the absence and presence of water and by volumetric titrations of the acid sites in cyclohexane and in water, to enlighten the nature and amount of acid sites in different environments. For both studied reactions, 2.5NbP catalyst exhibits water-tolerant acidic sites, mainly Brønsted ones, giving higher activity and better stability in the reaction medium than well-known niobium oxophosphate catalyst, which is considered one of the best water-tolerant acid catalysts

Substitution clustering in a non-stoichiometric celsian synthesized by the thermal transformation of barium exchanged zeolite X

The thermal transformation of Ba exchanged zeolite X to celsian has been studied by Al and Si MAS NMR spectroscopy. Evidence for the degradation of the zeolite framework is present in the Si NMR spectra after thermal treatment at 850 °C. Confirmation is provided by the Si NMR data that synthesis of celsian via the decomposition of Ba exchanged zeolite leads to a single defect phase. Clustering of the isomorphous replacement of aluminium by silicon must occur to explain the observed Si chemical shifts. The Al NMR data show distorted aluminium co-ordination sites upon the thermal transformation of Ba exchanged zeolite X. The distortions present in the amorphous matrix are greater than those present in the monoclinic and hexagonal crystalline phases of celsian

Solid state Si-29 and P-31 NMR study of gel derived phosphosilicate glasses

Solid state Si-29 and P-31 MAS NMR have been used to investigate the microstructural changes occurring in phosphosilicate gels during their conversion from a gel to the corresponding gel-derived glasses by heating. The studied gels have the molar compositions 10P(2)O(5). 90SiO(2) and 30P(2)O(5). 70SiO(2). It was found that the dried gels (100 degreesC) have very similar structures formed by a siloxane framework containing silanol groups and including trapped molecules of orthophosphoric acid along with a very small amount of pyrophosphoric acid. In spite of this initial similarity further heating causes markedly different structural rearrangements of their glassy matrices. Namely, the co-polymerisation of phosphate and silicate tetrahedra takes place at 300 degreesC for the gel with the higher phosphorus content whereas this occurs only after heat treatment for 30 minutes at 400 degreesC for the gel with the lower phosphorus content. Moreover, the presence of six-coordinated silicon in the glassy matrix of the 30P(2)O(5). 70SiO(2) gel has been observed. The different evolution of the investigated gel microstructures mirrors their different crystallization behaviour: 10P(2)O(5). 90SiO(2) keeps its amorphous nature up to 1000 degreesC while for 30P(2)O(5). 70SiO(2) crystallization starts after heat treatment for 30 minutes at 400 degreesC

NMR characterisation of the relationship between frustration and the excited state of Im7

Previous work shows that Im9 folds in a two-state transition while its homologue Im7 folds in a three-state transition via an on-pathway kinetic intermediate state (KIS), with this difference being related to frustration in the structure of Im7. We have used NMR spectroscopy to study conformational dynamics connected to the frustration. A combination of equilibrium peptide N(1)H/N(2)H exchange, model-free analyses of backbone NH relaxation data and relaxation dispersion (RD)-NMR shows that the native state of Im7 is in equilibrium with an intermediate state that is lowly populated [equilibrium intermediate state (EIS)]. Comparison of kinetic and thermodynamic parameters describing the EIS native-state equilibrium obtained by RD-NMR with previously reported parameters describing the KIS native-state equilibrium obtained from stopped-flow fluorescence studies of refolding His-tagged Im7 shows that the KIS and the EIS are the same species. (15)N chemical shifts of the EIS obtained from the RD-NMR analysis show that residues forming helix III in the native state are unstructured in the EIS while other residues experiencing frustration in the native state are in structured regions of the EIS. We show that binding of Im7 and its L53A/I54A variant (which resembles the EIS as shown in previous work) to the cognate partner for Im7, the DNase domain of colicin E7, causes the dynamic processes associated with the frustration to be dampened

Structural dynamics of the receptor-binding domain of colicin E9

Colicin E9 is a 61 kDa antibacterial protein secreted by E. coli. In order for it to enter the cytoplasm of susceptible bacteria and kill them by hydrolysing their DNA, the colicin must first interact with an outer membrane receptor on the target cell, BtuB, and a translocation pathway involving Tol proteins. The receptor binding, translocation and DNase functions of colicin E9 are housed in discrete structural domains, which have been independently expressed and characterized. The minimal receptor-binding domain is a 76 amino acid protein (min-R). X-ray structure determination of a related colicin shows its receptor-binding domain to have a helical hairpin structure (S. Soelaiman, K. Jakes, N. Wu, C. Li and M. Shoham, Molecular Cell, 2001, 8, 1053). Our solution NMR studies of min-R have confirmed it has a helical hairpin structure, and shown it has multiple slowly interchanging conformers and a flexible inter-helix loop. A plausible interpretation of these data is that in solution the helical hairpin can adopt a variety of structures differing in the spatial relationship of the two helices. A possible biological role for this involves the hairpin opening during translocation into bacteria