Decreased snake venom metalloproteinase effects via inhibition of enzyme and modification of fibrinogen

Since the introduction of antivenom administration 120 years ago to treat venomous snake bit, it has been the gold standard for saving life and limb. However, this therapeutic approach is not always effective and not without potential life-threatening side effects. We tested a new paradigm to abrogate the plasmatic anticoagulant effects of fibrinogenolytic snake venom metalloproteinases by modification of fibrinogen with iron and carbon monoxide and by inhibiting these Zn²⁺ dependent metalloproteinases directly with carbon monoxide exposure. Assessment of the fibrinogenolytic effects of venoms collected from Puff adder, Gaboon viper and Indian cobra snakes on plasmatic coagulation kinetics was performed with thrombelastography. Pretreatment of plasma with iron and carbon monoxide exposure markedly attenuated the effects of all three venoms, and direct pretreatment of each venom with carbon monoxide also significantly decreased the ability to compromise coagulation. These results demonstrated that the introduction of a transition metal (e.g., modulation of the α-chain of fibrinogen with iron), modulation of transition metal in heme (e.g., carbon monoxide modulation of fibrinogen-bound heme iron), and direct inhibition of transition metal containing venom enzymes (e.g., CO binding to Zn²⁺ or displacing Zn²⁺ from the catalytic site) significantly decreased fibrinogenolytic activity. This biometal modulation strategy to attenuate the anticoagulant effects of snake venom metalloproteinases could potentially diminish hemostatic injury in envenomed patients until antivenom can be administered.     

Association between the allele compositions of major plant developmental genes and frost tolerance in barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) germplasm of different origin

Changing climatic conditions with warming winters and shifts in the frequencies of drought, intense rainfall and cold spells together with associated changes in the geographical distribution of arable crops increase the challenges for selecting new varieties. In this context, we aim to contribute to a better understanding of the determinants of barley (Hordeum vulgare) frost tolerance (FRT) and consequent improvements to marker-assisted selection (MAS). Freezing injury in a diversity panel of 121 barley genotypes with different growth habits and origins was assessed using phenotyping based on chlorophyll fluorescence (F_v/F_m) measurements to screen genetic diversity in plants at an early growth stage. The haplotypes of vernalisation and photoperiod genes were determined with PCR, and correlation analyses were done using data from 12 laboratory and field-laboratory FRT tests. Previous results of allelic combinations of VRN-H1/VRN-H2 for FRT were confirmed with these experiments using a larger set of genotypes. The predictive power of polymorphisms in VRN-H1 intron 1 region for FRT was significantly higher than that of the VRN-H1 promoter polymorphism. The vrn-H1/vrn-H2 facultative genotypes had similar or higher FRT than vrn-H1/Vrn-H2 winter genotypes under suboptimal hardening conditions. Genes regulating long-day and short-day photoperiodic responses were significantly correlated with FRT. The most parsimonious model for prediction of FRT was based on polymorphisms in the VRN-H1 intron 1 region, VRN-H2 and PPD-H2 and explained 69% of the variation in FRT.     

Morphological and thermal properties of cellulose-montmorillonite nanocomposites

Cellulose-layered montmorillonite (MMT) nanocomposites were prepared by precipitation from N-methylmorpholine- N-oxide (NMMO)/water solutions. Two hybrid samples were obtained to investigate the influence of the reaction time on the extent of clay dispersion within the matrix. It was observed that longer contact times are needed to yield nanocomposites with a partially exfoliated morphology. The thermal and thermal oxidative properties of the hybrids, which might be of interest for fire-resistant final products, were investigated by thermogravimetry and chemiluminescence (CL). The nanocomposites exhibited increased degradation temperatures compared to plain cellulose, and the partially exfoliated sample showed the maximum stability. This result was explained in terms of hindered transfer of heat, oxygen, and degraded volatiles due to the homogeneously dispersed clay filler. Kinetic analysis of the decomposition process showed that the degradation of regenerated cellulose and cellulose-based hybrids occurred through a multistep mechanism. Moreover, the presence of nanoclay led to drastic changes in the dependence of the activation energy on the degree of degradation. CL analysis showed that longer permanence in NMMO/water solutions brought about the formation of carbonyl compounds on the polymer backbone. Moreover, MMT increased the rate of dehydration and oxidation of cellulose functional moieties. As a consequence, cellulose was found to be less stable at temperatures lower than 100 degrees C. Conversely, at higher temperatures, the hindering of oxygen transfer prevailed, determining an increase in thermo-oxidative stability.     

Assessing amendment properties of digestate by studying the organic matter composition and the degree of biological stability during the anaerobic digestion of the organic fraction of MSW

The transformation of organic matter during anaerobic digestion of mixtures of energetic crops, cow slurry, agro-industrial waste and organic fraction of municipal solid waste (OFMSW) was studied by analysing different samples at diverse points during the anaerobic digestion process in a full-scale plant. Both chemical (fiber analysis) and spectroscopic approaches (¹³C CPMAS NMR) indicated the anaerobic digestion process proceeded by degradation of more labile fraction (e.g. carbohydrate-like molecules) and concentration of more recalcitrant molecules (lignin and non-hydrolysable lipids). These modifications determined a higher degree of biological stability of digestate with respect to the starting mixture, as suggested, also, by the good correlations found between the cumulative oxygen uptake (OD₂₀), and the sum of (cellulose + hemicellulose + cell soluble) contents of biomasses detected by fiber analysis (r = 0.99; P < 0.05), and both O–alkyl-C (r = 0.98; P < 0.05) and alkyl-C (r = −0.99; P < 0.05) measured by ¹³C CPMAS NMR.     

Optimization of pyrazole inhibitors of Coactivator Associated Arginine Methyltransferase 1 (CARM1)

Design, synthesis, and SAR development led to the identification of the potent, novel, and selective pyrazole based inhibitor (7f) of Coactivator Associated Arginine Methyltransferase (CARM1).     

3-Amino-1,4,5,6-tetrahydropyrrolo[3,4-c]pyrazoles: a new class of CDK2 inhibitors

We have recently reported about a new class of Aurora-A inhibitors based on a bicyclic tetrahydropyrrolo[3,4-c]pyrazole scaffold. Here we describe the synthesis and early expansion of CDK2/cyclin A-E inhibitors belonging to the same chemical class. Synthesis of the compounds was accomplished using a solution-phase protocol amenable to rapid parallel expansion. Compounds with nanomolar activity in the biochemical assay and able to efficiently inhibit CDK2-mediated tumor cell proliferation have been obtained.     

Structural characterization of recombinant human myoglobin isoforms by (1)H and (129)Xe NMR and molecular dynamics simulations

Myoglobin (Mb), the main cytosolic oxygen storage/deliver protein, is also known to interact with different small ligands exerting other fundamental physiological roles. In Humans up to five different Mb isoforms are present. The two most expressed ones (>90%) differ only at the 54th position, K54 (Mb-I) and E54 (Mb-II) respectively. High-altitude populations are characterized by a higher Mb concentration in skeletal muscle, totally attributable to Mb-II, as well as a higher efficiency of locomotion, leading to the hypothesis of a cause-effect relationship with the evolutionary response to the high-altitude hypoxic environment. In this work, a first structural characterization of the two more expressed human Mb isoforms has been carried out. In particular, a detailed (1)H and (129)Xe NMR study was aimed to characterize the structure of the hydrophobic cavities around the heme group. Experimental results have been compared to those from MD simulations, i.e. volume fluctuations and occurrence. Electronic structure of the heme ring ground state resulted to be comparable for the two investigated isoforms, despite the single point mutation at position 54. However, the use of (129)Xe as a probe revealed small but significant modifications in the structure of internal cavities. MD simulations supported NMR results indicating interesting structural/dynamical differences in the average volume and occurrence of the main cavities lining Mb prosthetic group.