Isolation and characterization of Aspergillus sp. for the production of extracellular polysaccharides by response surface methodology

In this study, Aspergillus sp. was isolated for the production of extracellular polysaccharide. The process parameters were initially optimized by traditional methods. The cheap substrate, wheat bran was used for the production of extracellular polysaccharide in solid state fermentation. Supplementation of (1%, w/w) maltose, gelatin enhanced EPS production (5.36?mg/g). The salts such as, Cu²⁺ (4.9?mg/g), Ca²⁺ (3.5?mg/g), Zn²⁺ (2.9?mg/g), Mn²⁺ (3.4?mg/g) and Mg²⁺ (1.8?mg/g) stimulated EPS production. In two level full factorial experimental designs, the EPS yield varied from 3.18 to 11.65?mg/g wheat bran substrate with various combinations of the components supplemented with wheat bran substrate. Among these selected factors in central composite design, maltose significantly influenced on extracellular polysaccharide production.     

Spectral and structural analysis of a red fluorescent protein from Acropora digitifera

Fluorescent proteins (FPs) possess a wide variety of spectral properties that make them of widespread interest as optical markers. These proteins can be applied as pH indicators or metal biosensors. The discovery and characterization of new fluorescent proteins is expected to further extend their application. Here, we report the spectral and structural analysis of a red fluorescent protein from Acropora digitifera (designated AdRed). This protein shows a tetrameric state and is red emitting, with excitation and emission maxima at 567 and 612 nm, respectively. Its crystal structure shows the tetrameric interface stabilized by hydrogen bonding and salt bridges. The electron density map of the chromophore, consisting of Asp66–Tyr67–Gly68, shows the decarboxylated side chain of Asp66. Ser223, located near the chromophore, has the role of bridging His202 and Glu221, and is part of the hydrogen bond network. Mutated AdRed with Cys148Ser reveals a blue shift in fluorescence excitation and emission. Our results provide insights into understanding the molecular function of AdRed and other FPs.     

Urinary nucleic acid oxidation product levels show differential associations with pharmacological treatment in patients with type 2 diabetes

The relationship between RNA and DNA oxidation and pharmacological treatment has not been systematically investigated in patients with type 2 diabetes (T2D). We aimed to investigate the association between pharmacological treatments and levels of urinary markers of nucleic acid oxidation in T2D patients. Vejle Diabetes Biobank cohort data was nested into nationwide registry data. Multiple logistic regression was used to associate drug usage with risk of high (above median) RNA and DNA oxidation. Data from 2664 T2D patients (64% male, age range: 25–75) were included. Questionnaire-validated lipid lowering drug use was associated with low RNA oxidation (Odds ratio, OR 0.71, 95% CI: [0.59–0.87]). Insulin and non-specific antidiabetic drugs were associated with low DNA oxidation (insulin: OR 0.60, 95% CI [0.49–0.73]). Oral antidiabetics were associated with high DNA oxidation and RNA oxidation (OR 1.30, 95% CI [1.10–1.53] and OR 1.26, 95% CI [1.07–1.29]). Our findings indicate that diabetes-related drugs are associated with RNA and DNA oxidation and further studies are required to determine causality in T2D patients.     

Newly Identified HNP‐F from Human Neutrophil Peptide‐1 Promotes Hemostasis

Active hemostatic agents can play a crucial role in saving patients’ lives during surgery. Active hemostats have several advantages including utilization of natural blood coagulation and biocompatibility. Among them, although human neutrophil peptide‐1 (HNP‐1) has been previously reported with the hemostatic mechanism, which part of HNP‐1 facilitates the hemostatic activity is not known. Here, a partial peptide (HNP‐F) promoting hemostasis, originating from HNP‐1, has been newly identified by the blood coagulation ability test. HNP‐F shows the best hemostatic effect between the anterior half and posterior half of peptides. Moreover, microscopic images show platelet aggregation and an increase in the concentration of platelet factor 4, and the scanning electron microscope image of platelets support platelet activation by HNP‐F. Thromboelastography indicates decreased clotting time and increased physical properties of blood clotting. Mouse liver experiments demonstrate improved hemostatic effect by treatment of peptide solution. Cell viability and hemolysis assays confirm the HNP‐F's biosafety. It is hypothesized that the surface charge and structure of HNP‐F could be favorable to interact with fibrinogen or thrombospondin‐1. Collectively, because HNP‐F as an active peptide hemostat has many advantages, it could be expected to become a potent hemostatic biomaterial, additive or pharmaceutical candidate for various hemostatic applications.     

Bioaugmentation of a two-stage thermophilic (68 degrees C/55 degrees C) anaerobic digestion concept for improvement of the methane yield from cattle manure

The possibility of improving a two-stage (68 degrees C/55 degrees C) anaerobic digestion concept for treatment of cattle manure was studied. In batch experiments, a 10-24% increase of the specific methane yield from cattle manure and its fractions was obtained, when the substrates were inoculated with bacteria of the genus Caldicellusiruptor and Dictyoglomus. In a reactor experiment inoculation of a 68 degrees C pretreatment reactor with Caldicellusiruptor resulted in a 93% increase in the methane yield of the pretreatment reactor for a period of 18 days, but gave only a slight increase in the overall methane yield of the two-stage setup.     

Intermediate filaments and stress

Before we can explain why so many closely related intermediate filament genes have evolved in vertebrates, while maintaining such dramatically tissue specific expression, we need to understand their function. The best evidence for intermediate filament function comes from observing the consequences of mutation and mis-expression, primarily in human tissues. Mostly these observations suggest that intermediate filaments are important in allowing individual cells, the tissues and whole organs to cope with various types of stress, in health and disease. Exactly how they do this is unclear and many aspects of cell dysfunction have been associated with intermediate filaments to date. In particular, it is still not clear whether the non-mechanical functions now being attributed to intermediate filaments are primary functions of these structural proteins, or secondary consequences of their function to respond to mechanical stress. We discuss selected situations in which responses to stress are clearly influenced by intermediate filaments.     

Glenohumeral mobility in primates

This study refutes the traditional idea that the glenohumeral joint of hominoids is more mobile than that of other primates, a belief that forms a basis for the two prominent theories of hominoid evolution. According to the brachiation theory, many anatomical features of the hominoid shoulder (including those of the glenohumeral joint) increase shoulder mobility and are interpreted as adaptations for brachiation. The slow climbing theory explains the same set of features as adaptations for slow climbing. The slow-climbing primates should therefore also possess these features, and their glenohumeral mobility should be the same as that of hominoids and be higher than that of other primates. This study presents three-dimensional glenohumeral mobility data, measured using a single video camera method on fresh specimens. The results show that the hominoid glenohumeral joint is actually less mobile than those of non-hominoid primates, including the habitually slow-climbing lorines, but it is characterized by a smooth excursion in the scapulocranial direction.     

dXNP, a Drosophila homolog of XNP/ATRX, induces apoptosis via Jun-N-terminal kinase activation

XNP/ATRX, a causative gene of X-linked alpha-thalassemia/mental retardation syndrome, encodes an SNF2 family ATPase/helicase protein. To better understand the role of XNP/ATRX in development, we isolated and characterized a Drosophila XNP/ATRX homolog, dXNP, which contains highly conserved SNF2 and helicase domains. Ectopically expressed dXNP induced strong apoptosis in the developing eye and wing, but did not affect cell cycle progression or the expression of wingless and engrailed, essential regulators of development. The dXNP-induced apoptosis was strongly suppressed by DJNKK/hemipterous mutation, and dXNP increased JNK activity. Taken together, these results suggest that dXNP regulates apoptosis via JNK activation.