Operant escape learning in decerebrate duck embryos.

Trained 192 Peking duck embryos (Anas platythynchos) in an operant escape task on Day 25 of incubation (total incubation period of 27 days) following decerebration on Day 24. Experimental embryos successfully acquired the operant response, which involved the performance of a discrete foot flexion to terminate a shock applied to the wing. The decerebrate embryos resembled normal unoperated embryos of this age in their acquisition of the operant behavior. Results demonstrate that this form of learning can be acquired without benefit of telencephalic structures, at least at this point in development. Differences in the consequences of decerebration during prenatal or neonatal vs adult stages are discussed. (13 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Physicochemical Characterization of Wheat Straw during a Continuous Pretreatment Process

The changes occurring during the depolymerization of lignocellulosic biomasses are not yet fully understood. Synchrotron micro‐Fourier transform infrared (µ‐FTIR), Raman spectroscopy (RS), X‐ray diffraction (XRD), and X‐ray fluorescence (XRF) were applied for better characterization of wheat straw fibers during a continuous pretreatment process in terms of conditioning (C), extrusion (E), steam explosion (SE), and enzymatic hydrolysis (EH). µ‐FTIR revealed functional groups as phenylpropanoid polymers, ethers, and aliphatic alcohol. RS detected acetoacetate, methyl and phenol groups after SE. The crystallinity index and silica content were also determined.     

Hydrogen production by fermentative consortia

In this work, H₂ production by anaerobic mixed cultures was reviewed. First, the different anaerobic microbial communities that have a direct relation with the generation or consumption of H₂ are discussed. Then, the different methods used to inhibit the H₂-consuming bacteria are analyzed (mainly in the methanogenesis phase) such as biokinetic control (low pH and short hydraulic retention time), heat-shock treatment and chemical inhibitors along with their advantages/disadvantages for their application on an industrial scale. After that, biochemical pathways of carbohydrate degradation to H₂, organic acids and solvents are showed. Fourth, structure, diversity and dynamics of H₂-producers communities are detailed. Later, the hydrogenase structure and activity is related with H₂ production. Also, the causes for H₂ production inhibition are analyzed along with strategies to avoid it. Finally, immobilized-cells systems are presented as a way to enhance H₂ production.     

Biochemical characterization of an isoform of chymotrypsin from the viscera of Monterey sardine (Sardinops sagax caerulea), and comparison with bovine chymotrypsin

Chymotrypsin II from the viscera of Monterey sardine was characterized as an isoform of chymotrypsin I previously characterized from the same source and compared with bovine chymotrypsin. Chymotrypsin II had a molecular weight of 25,500 Da, similar to bovine chymotrypsin. The isoform identity as chymotrypsin was established by its catalytic specificity on the specific substrates succinyl-l-ala-ala-pro-l-phenylalanine-p-nitroanilide and benzoyl-l-tyrosine ethyl ester, showing higher specific activity than bovine chymotrypsin. Both enzymes showed maximal activity at pH 8.0, chymotrypsin II being stable at alkaline pH while bovine chymotrypsin was stable at acid and alkaline pH. Optimum temperature was 45 °C for chymotrypsin II and 55 °C for bovine chymotrypsin. Both enzymes were inhibited by phenylmethylsulfonyl-fluoride and soybean trypsin inhibitor, and partially by N-toluenesulfonyl-l-phenylalanine chloromethyl-ketone. This is valid only in specific conditions of this work. K_m and k_cat for chymotrypsin II were 0.048 mM and 4.8 s⁻¹, and 0.09 mM and 1.9 s⁻¹ for bovine chymotrypsin. Catalytic efficiency of chymotrypsin II was 4.8-fold higher than bovine chymotrypsin.     

Alkalinity and high total solids affecting H2 production from organic solid waste by anaerobic consortia

The optimization of total solids in the feed (%TS) and alkalinity ratio (γ) for H₂ production from organic solid wastes under thermophilic regime was carried out using response surface methodology based on a central composite design. The total solids levels were 20.9, 23.0, 28.0, 33.0 and 35.1% whereas the levels of alkalinity ratio (defined as g phosphate alkalinity/g dry substrate) were 0.15, 0.20, 0.30, 0.41 and 0.45. High levels of TS and γ affected in a negative way the H₂ productivity and yield; both response variables significantly increased upon decreasing the TS content and alkalinity ratio. The highest H₂ productivity and yield were 463.7 N mL/kg-d and 54.8 N mL/g VS_rem, respectively, predicted at 20.9% TS and alkalinity ratio 0.25 (0.11 g CaCO₃/g dry substrate). The alkalinity requirements for hydrogenogenic processes were lower than those reported for methanogenic processes (0.11 vs. 0.30 g CaCO₃/g COD). Adequate alkalinity ratio was necessary to maintain optimal biological activity for hydrogen production; however, excessive alkalinity negatively affected process performance probably due to an increase of osmotic pressure. Interestingly, reactor pH depended only on the alkalinity ratio, thus the buffer capacity was able to maintain a constant pH independently of TS levels. At γ = 0.15–0.30 the pHs were in the range 5.56–5.95, which corresponded to the highest hydrogen productivities and yields. Finally, the highest metabolite accumulation corresponded with the highest removal efficiencies but not with high H₂ productivities and yields. Therefore, it seems that organic matter removal was channeled toward solvent generation instead of hydrogen production at high TS and γ levels. This is the first study that shows the requirements of alkalinity in solid substrate fermentation conditions for H₂ production processes and their interaction with the content of total solids in the feed.     

Thermodynamic activation and structural analysis of trypsin I from Monterey sardine (Sardinops sagax caerulea)

In this work, we report the molecular characterisation of trypsin I (Try I) from Monterey sardine (Sardinops sagax caerulea). Aspects such as thermodynamic activation parameters, molecular model and cDNA-deduced amino acid sequence allow a more in depth understanding of its activity at low temperatures. The analysis of the thermodynamic activation parameters suggests that this molecule is a cold-adapted protease. From the molecular cloning, we deduced the amino acid sequence and predicted a theoretical structural model of sardine Try I with a classical trypsin fold. Cold-adaptation of this enzyme probably comes from amino acid replacement of key residues to improve flexibility at low temperature, thus increasing k_cat. The cold-adaptation of sardine Try I opens a wide range of biotechnological applications for this protease and also it is interesting from the structure function relationship point of view of serine protease proteins.     

Improvement of biohydrogen production from solid wastes by intermittent venting and gas flushing of batch reactors headspace

Headspace of batch minireactors was intermittently vented and gas flushed with N2 in order to enhance H2 production (PH) by anaerobic consortia degrading organic solid wastes. Type of inocula (meso and thermophilic), induction treatment (heat-shock pretreatment, HSP, and acetylene, Ac), and incubation temperature (37 and 55 degrees C) were studied by means of a factorial design. On average, it was found that mesophilic incubation had the most significant positive effect on PH followed by treatment with Ac, although the units with the best performance (high values of PH, initial hydrogen production rate, and short lag time) were those HSP-induced units incubated at 37 degrees C (type of inocula was not significant). In this way, after 720 h of incubation PH was inhibited in those units by H2 partial pressure (pH2) of 0.54 atm. Venting and gas flushing with N2 was efficient to eliminate that inhibition achieving additional hydrogen generation in subsequent incubation cycles although smaller than the first one. Thus, four cycles of PH were obtained from the same substrate with neither addition of inocula nor application of induction treatment obtaining an increment of 100% in the generated H2. In those subsequent cycles there was a positive correlation between PH and organic acids/solvent ratio; maximum values were found in the first cycle. Solventogenesis could be clearly distinguished in third and fourth production cycles, probably due to a metabolic shift originated by high organic acid concentrations.     

Distribution and potential of bioenergy resources from agricultural activities in Mexico

Biomass is the most abundant and versatile form of renewable energy in the world. The bioenergy production from crop residues is compatible with both food and energy production. Currently, several technologies are available for transforming crop residues into utilizable energy such as direct combustion and fermentation. Mexico is the third largest country in LAC in terms of the cropland area and would become a central focus of attention for the production of biofuels. In this paper we examined the type, location and quantities of various crop residues in Mexico to evaluate their potential for conversion into bioenergy through combustion and fermentation. It was estimated that 75.73 million tons of dry matter was generated from 20 crops in Mexico. From this biomass, 60.13 million tons corresponds to primary crop residues mainly from corn straw, sorghum straw, tops/leaves of sugarcane and wheat straw. The generation of secondary crop residues accounted for 15.60 million tons to which sugarcane bagasse, corncobs, maguey bagasse and coffee pulp were the main contributors. The distribution of this biomass showed that several Mexican municipalities had very high by-product potentials where each municipality could have an installed capacity of 78 MW (via direct combustion) or 0.3 million m³ of bioethanol per year (via anaerobic fermentation). The identification of these municipalities where the biomass potential is high is important since it constitutes the first step towards evaluating the current biomass availability and accurately estimating the bioenergy production capacity from crop residues.     

Modulation of biotransformation and elimination systems by BM-21, an aqueous ethanolic extract from Thalassia testudinum,and thalassiolin B on human hepatocytes

BM-21 is an extract obtained from Thalassia testudinum marine plant with pharmacological properties. The effects of BM-21 and thalassiolin B (TB), its main component, on enzyme and transport proteins involved in drug metabolism and excretion in human cultured hepatocytes were evaluated. Cells were exposed for 48 h to sub-cytotoxic concentrations of BM-21 or TB. Effects on P450 isoforms revealed significant reductions of CYP1A2, 3A4 and 2D6 activities (up to 56%, 66% and 44% inhibition, respectively) after exposition to BM-21, no changes on CYP2A6 and 2C9 activities. TB produced a concentration-dependent reduction of all P450 activities. In addition, a decrease in total UGT and UGT2B7 activities was found at 250 μg/mL BM-21, while UGT1A1 and 1A9 were significantly reduced (50 μg/mL). TB only inhibited significantly UGT1A9 activity. Both products were able to reduce P-gp activity in treated hepatocytes. Quantification of specific mRNAs revealed a reduction in CYP3A4 and 3A5 mRNAs content and an increase in CYP1A1 and 1A2 mRNAs. No appreciable effects in the levels of CYP2A6, 2B6, 2C9, 2C19, 2D6, 2E1, UGT1A1, UGT1A9 and ABCB1 (P-gp) were found. BM-21 inhibited P450, UGTs and P-gp activities in human hepatocytes; therefore, it should be examined for potential pharmacokinetic drug interactions in vivo.     

Nutrients related to spore germination improve H2 production from heat-shock-treated consortia

The effect of supplementation of specific nutrients related to spore germination on batch hydrogen production from heat-shock-pretreated (HSP) consortia and organic solid waste was studied. A 2 × 3 general factorial design was used to evaluate the effect of incubation temperature (two levels) and addition of specific nutrients for spore germination, named germinants (three levels) on hydrogen production. l-Alanine alone (A1) and a mixture of germinants (A2) were used as specific nutrients as well as control without germinants (A3). The units were incubated at 37 °C (B1) or 55 °C (B2). The analysis of variance showed that both factors had highly significant effects on hydrogen production (p < 0.0001). The best performance was obtained in HSP units supplemented with l-alanine alone followed by the mixture of germinants whereas those HSP units without germinants supplementation had very poor H₂ production. The average results for incubation temperature showed that independently of germinant addition, the mesophilic regime showed higher H₂ production, likely related to more benign germination conditions, than thermophilic incubation. This study demonstrates that hydrogen batch production from HSP consortia and organic solid waste as substrate could be substantially improved by germinant supplementation, although more-detailed studies on individual germinants or germinant combinations and their concentrations are necessary.