FT-IR,FT-Raman spectra and DFT vibrational analysis of 2-aminobiphenyl

In this work, the Fourier transform infrared (FT-IR) and Fourier transform Raman (FT-Raman) spectra of 2-aminobiphenyl (2ABP) were recorded in the solid phase. The optimised geometry, frequency and intensity of the vibrational bands of 2ABP were obtained by the density functional theory (BLYP and B3LYP) methods with complete relaxation in the potential energy surface using 6-31G(d) basis set. The harmonic vibrational frequencies were calculated and the scaled values have been compared with experimental FT-IR and FT-Raman spectra. The observed and the calculated frequencies are found to be in good agreement. The experimental spectra also coincide satisfactorily with those of theoretically constructed spectrograms.     

A landscape-level assessment of Asian elephant habitat,its population and elephant–human conflict in the Anamalai hill ranges of southern Western Ghats,India

Spatial information at the landscape scale is extremely important for conservation planning, especially in the case of long-ranging vertebrates. The biodiversity-rich Anamalai hill ranges in the Western Ghats of southern India hold a viable population for the long-term conservation of the Asian elephant. Through rapid but extensive field surveys we mapped elephant habitat, corridors, vegetation and land-use patterns, estimated the elephant population density and structure, and assessed elephant–human conflict across this landscape. GIS and remote sensing analyses indicate that elephants are distributed among three blocks over a total area of about 4600 km². Approximately 92% remains contiguous because of four corridors; however, under 4000 km² of this area may be effectively used by elephants. Nine landscape elements were identified, including five natural vegetation types, of which tropical moist deciduous forest is dominant. Population density assessed through the dung count method using line transects covering 275 km of walk across the effective elephant habitat of the landscape yielded a mean density of 1.1 (95% CI = 0.99–1.2) elephant/km². Population structure from direct sighting of elephants showed that adult male elephants constitute just 2.9% and adult females 42.3% of the population with the rest being sub-adults (27.4%), juveniles (16%) and calves (11.4%). Sex ratios show an increasing skew toward females from juvenile (1:1.8) to sub-adult (1:2.4) and adult (1:14.7) indicating higher mortality of sub-adult and adult males that is most likely due to historical poaching for ivory. A rapid questionnaire survey and secondary data on elephant–human conflict from forest department records reveals that villages in and around the forest divisions on the eastern side of landscape experience higher levels of elephant–human conflict than those on the western side; this seems to relate to a greater degree of habitat fragmentation and percentage farmers cultivating annual crops in the east. We provide several recommendations that could help maintain population viability and reduce elephant–human conflict of the Anamalai elephant landscape.     

Thermal behaviour and tolerance to ionic liquid [emim]OAc in GH10 xylanase from Thermoascus aurantiacus SL16W

GH10 xylanase from Thermoascus aurantiacus strain SL16W (TasXyn10A) showed high stability and activity up to 70–75 °C. The enzyme’s half-lives were 101 h, 65 h, 63 min and 6 min at 60, 70, 75 and 80 °C, respectively. The melting point (T _m), as measured by DSC, was 78.5 °C, which is in line with a strong activity decrease at 75–80 °C. The biomass-dissolving ionic liquid 1-ethyl-3-methylimidazolium acetate ([emim]OAc) in 30 % concentration had a small effect on the stability of TasXyn10A; T _m decreased by only 5 °C. It was also observed that [emim]OAc inhibited much less GH10 xylanase (TasXyn10A) than the studied GH11 xylanases. The K _m of TasXyn10A increased 3.5-fold in 15 % [emim]OAc with xylan as the substrate, whereas the approximate level of V _max was not altered. The inhibition of enzyme activity by [emim]OAc was lesser at higher substrate concentrations. Therefore, high solid concentrations in industrial conditions may mitigate the inhibition of enzyme activity by ionic liquids. Molecular docking experiments indicated that the [emim] cation has major binding sites near the catalytic residues but in lower amounts in GH10 than in GH11 xylanases. Therefore, [emim] cation likely competes with the substrate when binding to the active site. The docking results indicated why the effect is lower in GH10.     

Hyperthermostable <Emphasis Type="Italic">Thermotoga maritima</Emphasis> xylanase XYN10B shows high activity at high temperatures in the presence of biomass-dissolving hydrophilic ionic liquids

The gene of Thermotoga maritima GH10 xylanase (TmXYN10B) was synthesised to study the extreme limits of this hyperthermostable enzyme at high temperatures in the presence of biomass-dissolving hydrophilic ionic liquids (ILs). TmXYN10B expressed from Pichia pastoris showed maximal activity at 100 °C and retained 92 % of maximal activity at 105 °C in a 30-min assay. Although the temperature optimum of activity was lowered by 1-ethyl-3-methylimidazolium acetate ([EMIM]OAc), TmXYN10B retained partial activity in 15–35 % hydrophilic ILs, even at 75–90 °C. TmXYN10B retained over 80 % of its activity at 90 °C in 15 % [EMIM]OAc and 15–25 % 1-ethyl-3-methylimidazolium dimethylphosphate ([EMIM]DMP) during 22-h reactions. [EMIM]OAc may rigidify the enzyme and lower V _max. However, only minor changes in kinetic parameter K _m showed that competitive inhibition by [EMIM]OAc of TmXYN10B is minimal. In conclusion, when extended enzymatic reactions under extreme conditions are required, TmXYN10B shows extraordinary potential.     

Molecular modeling of 4-methylphthalonitrile for dye sensitized solar cells using quantum chemical calculations

The geometries, electronic structures, polarizabilities, and hyperpolarizabilities of organic dye sensitizer 4-Methylphthalonitrile was studied based on Hartree-Fock (HF) and density functional theory (DFT) using the hybrid functional B3LYP. Ultraviolet-visible (UV-Vis) spectrum was investigated by time dependent-density functional theory (TD-DFT). Features of the electronic absorption spectrum in the visible and near-UV regions were assigned based on TD-DFT calculations. The absorption bands are assigned to π → π* transitions. Calculated results suggest that three lowest energy excited states of 4-Methylphthalonitrile are due to photo induced electron transfer processes. The interfacial electron transfer between semiconductor TiO₂ electrode and dye sensitizer 4-Methylphthalonitrile is due to an electron injection process from excited dye to the semiconductor’s conduction band. The role of cyanine and methyl group in 4-Methylphthalonitrile in geometries, electronic structures, and spectral properties were analyzed.     

Sequence selectivity of azinomycin B in DNA alkylation and cross-linking: a QM/MM study

Azinomycin B—a well-known antitumor drug—forms cross-links with DNA through alkylation of purine bases and blocks tumor cell growth. This reaction has been modeled using the ONIOM (B3LYP/6-31?+?g(d):UFF) method to understand the mechanism and sequence selectivity. ONIOM results have been checked for reliability by comparing them with full quantum mechanics calculations for selected paths. Calculations reveal that, among the purine bases, guanine is more reactive and is alkylated by aziridine ring through the C10 position, followed by alkylation of the epoxide ring through the C21 position of Azinomycin B. While the mono alkylation is controlled kinetically, bis-alkylation is controlled thermodynamically. Solvent effects were included using polarized-continuum-model calculations and no significant change from gas phase results was observed.

India's biodiversity hotspot under anthropogenic pressure: A case study of Nilgiri Biosphere Reserve

This paper presents data on the impact of biotic pressure in terms of grazing by livestock and wood cutting by humans on the plant community in the Nilgiri Biosphere Reserve of India. Grass, and herbaceous plant biomass, number of cattle dung piles, number of woody stems available and damaged by human activities and weed biomass were assessed at different proximity along transects radiating from village-forest boundary to forest interior to measure the ecological impact of livestock grazing and fire wood collection. The grass biomass was positively correlated to overgrazing indicating the adverse effect on natural vegetation by cattle. Woodcutting was intense along the forest boundary and significantly declined as distance increased. Similarly, weed biomass and number of thorny species declined positively with proximity from village-forest boundary and the weed biomass was significantly higher in the pastoral sites compared to residential sites. The results suggest that human impact adversely affects natural vegetation and promotes weed proliferation in forest areas adjoining human settlements in the ecologically important Nilgiri Biosphere Reserve. Continued anthropogenic pressure could cause reduction in fodder availability to large herbivores like elephants, which in turn leads to an increase in human–elephant conflict.     

Effect of Glycosylation and Additional Domains on the Thermostability of a Family 10 Xylanase Produced by Thermopolyspora flexuosa

The effects of different structural features on the thermostability of Thermopolyspora flexuosa xylanase XYN10A were investigated. A C-terminal carbohydrate binding module had only a slight effect, whereas a polyhistidine tag increased the thermostability of XYN10A xylanase. In contrast, glycosylation at Asn26, located in an exposed loop, decreased the thermostability of the xylanase. The presence of a substrate increased stability mainly at low pH.The thermophilic actinomycete Thermopolyspora flexuosa, previously named Nonomuraea flexuosa and before that Actinomadura flexuosa or Microtetraspora flexuosa (15), produces family 11 and family 10 xylanases, which show high thermostability (16, 17, 22). T. flexuosa xylanase XYN10A has a C-terminal family 13 carbohydrate binding module (CBM) (22). Many xylanases have an additional CBM, which can be a cellulose binding domain (CBD) or a xylan binding domain (XBD) (1, 5, 7, 22, 25, 28). XBD typically increases activity against insoluble xylan (1, 5, 24), although some XBDs also bind soluble xylans (21, 25).We studied the thermostability of T. flexuosa xylanase XYN10A and how CBM and other additional groups affect its thermostability. In addition to confirming the previously described importance of terminal regions, our study identified a loop that is important for the thermostability of T. flexuosa XYN10A. In general, identification of sites important for protein stability is necessary for targeted mutagenesis attempts to increase thermostability.The T. flexuosa xyn10A gene (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AJ508953","term_id":"57897980","term_text":"AJ508953"}}AJ508953) (22), which encodes the full-length XYN10A xylanase (1-AAST… SYNA-448) containing the catalytic domain and CBM, and a truncated gene, which encodes the catalytic domain only (1-AAST… DALN-301) were expressed in Trichoderma reesei as 3′ fusions to a sequence that encodes the Cel6A CBD (A+B) carrier polypeptide and a Kex2 cleavage site (RDKR) (27). In this article, the catalytic domain and the full-length enzyme are referred to as XYN10A and XYN10A-CBM, respectively. The catalytic domain was also produced in Escherichia coli. For production in E. coli, the sequence encoding the catalytic domain was cloned into a pKKtac vector (33) with and without an additional 3′ sequence encoding a 6×His tag at the protein C terminus (… DALNHHHHHH).The proteins were purified by hydrophobic interaction chromatography using a Phenyl Sepharose column and by ion-exchange chromatography using a DEAE Sepharose FF column (Amersham Pharmacia Biotech). The 6×His-tagged XYN10A xylanase produced in E. coli was purified by affinity chromatography using Ni-nitrilotriacetic acid (Ni-NTA) agarose beads (Qiagen).Mass spectrometric (MS) analyses were performed on a high-resolution 4.7-T hybrid quadrupole-Fourier transform ion cyclotron resonance (FT-ICR) instrument (APEX-Qe; Bruker Daltonics), which employs electrospray ionization (ESI) (see supplemental material for details).Xylanase activity was measured with a 3,5-dinitrosalicylic acid assay by using 1% solubilized birchwood xylan as a substrate (33). The optimum temperature, residual activity, and half-life assays were performed as described earlier (36). SWISS-MODEL (4) was used to automatically model T. flexuosa XYN10A and XYN10A-CBM (PDB codes for the modeling templates are 1v6w and 1e0w, respectively [12, 14]).The results of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis indicated that the masses of XYN10A xylanase and XYN10A-CBM produced in Trichoderma reesei were ∼37 kDa and ∼50 kDa, respectively (Fig. ​(Fig.1A).1A). MS analysis of the 6×His-tagged XYN10A produced in E. coli (SDS-PAGE not shown) indicated the presence of a single protein form (Fig. ​(Fig.1B),1B), with a measured mass of 34,943.25 Da. This is consistent with the theoretical mass of 6×His-tagged XYN10A (34,942.93 Da). In contrast, XYN10A produced in T. reesei was heterogeneously modified, and six protein forms (numbered 1 to 6) were detected (Fig. ​(Fig.1B).1B). The mass of form 1 (34,120.76 Da) is in excellent agreement with the calculated mass of XYN10A (34120.73 Da). The masses of forms 2 and 3, with mass increments of ∼203 and ∼162 Da, respectively, suggested protein glycosylation (+203 Da = GlcNAc; +162 Da = Man). There are two potential sites for N-glycosylation in XYN10A, Asn26 and Asn95. These six protein forms were resolved only by the high-resolution FT-ICR MS technique, not by SDS-PAGE (eluted as a single band [Fig. ​[Fig.1A1A]).Open in a separate windowFIG. 1.(A) SDS-PAGE of purified XYN10A and XYN10A-CBM produced in Trichoderma reesei. Lane 1, molecular weight markers; lane 2, catalytic domain (XYN10A); lane 3, full-length enzyme (XYN10A-CBM). (B) ESI FT-ICR mass spectra of XYN10A with a 6×His tag produced in E. coli (bottom) and XYN10A produced in T. reesei (top). Only the expanded view at m/z 1260 to 1300, with the signals representing the most abundant protein ion charge state z = 27+, is presented. For the measured and calculated masses of the protein forms identified, see the supplemental material.In order to locate the glycosylation site or sites, XYN10A proteins produced in E. coli and T. reesei were subjected to on-line pepsin digestion (see supplemental material for details). The sequence coverage for XYN10A xylanase produced in E. coli was 62%. For XYN10A produced in T. reesei, a lower sequence coverage was obtained, but three glycopeptides (residues 20 to 44, 20 to 46, and 20 to 59), carrying one GlcNAc residue, were detected (glycopeptides A to C in Fig. S1B in the supplemental material). A triply charged glycopeptide A was further analyzed by collision-induced dissociation (CID) measurement (see inset in Fig. S1B in the supplemental material). A ladder of b-type fragment ions further identified this peptide and verified Asn26 as the N-glycosylation site in XYN10A, carrying GlcNAc(Man) as a glycan core structure.The additional sequences attached to the catalytic domain affected the thermostability of XYN10A xylanase. The deletion of the native C-terminal CBM domain (XYN10A produced in T. reesei) slightly decreased (∼2°C) the apparent temperature optimum in the region of 70 to 75°C (Table ​(Table11 and Fig. ​Fig.2A).2A). However, at 80°C, the deletion of the CBM domain increased the activity (Fig. ​(Fig.2A).2A). Furthermore, the half-life in the presence of the substrate at 80°C was lower when the CBM was present (Table ​(Table22).Open in a separate windowFIG. 2.Enzyme activity and stability profiles. (A) Enzyme activity as a function of temperature. The enzymes were incubated for 30 min at each temperature at pH 7. (B) Enzyme inactivation as a function of temperature. The enzyme samples were incubated without the substrate for 30 min at each temperature (pH 7), and the residual activity was measured at 70°C. Values are means ± standard deviations (error bars) for three experiments. Symbols: ⧫, XYN10A xylanase produced in T. reesei; ⋄, XYN10A-CBM produced in T. reesei; ▪, XYN10A produced in E. coli; □, XYN10A-6×His produced in E. coli.

TABLE 1.

Peaks of the optimum temperatures (30-min assay)^a

High stability and low competitive inhibition of thermophilic Thermopolyspora flexuosa GH10 xylanase in biomass-dissolving ionic liquids

Thermophilic Thermopolyspora flexuosa GH10 xylanase (TfXYN10A) was studied in the presence of biomass-dissolving hydrophilic ionic liquids (ILs) [EMIM]OAc, [EMIM]DMP and [DBNH]OAc. The temperature optimum of TfXYN10A with insoluble xylan in the pulp was at 65–70 °C, with solubilised 1 % xylan at 70–75 °C and with 3 % xylan at 75–80 °C. Therefore, the amount of soluble substrate affects the enzyme activity at high temperatures. The experiments with ILs were done with 1 % substrate. TfXYN10A can partially hydrolyse soluble xylan even in the presence of 40 % (v/v) ILs. Although ILs decrease the apparent temperature optimum, a surprising finding was that at the inactivating temperatures (80–90 °C), especially [EMIM]OAc increases the stability of TfXYN10A indicating that the binding of IL molecules strengthens the protein structure. Earlier kinetic studies showed an increased K _m with ILs, indicating that ILs function as competitive inhibitors. TfXYN10A showed low increase of K _m, which was 2-, 3- and 4-fold with 15 % [EMIM]OAc, [DBNH]OAc and [EMIM]DMP, respectively. One reason for the low competitive inhibition could be the high affinity to the substrate (low K _m). Xylanases with low K _m (~1 mg/mL) appear to show higher tolerance to ILs than xylanases with higher K _m (~2 mg/mL). Capillary electrophoresis showed that TfXYN10A hydrolyses xylan to the end-products in 15–35 % ILs practically as completely as without IL, also indicating good binding of the short substrate molecules by TfXYN10A despite of major apparent IL binding sites above the catalytic residues. Substrate binding interactions in the active site appear to explain the high tolerance of TfXYN10A to ILs.