Pressure-induced structural changes of pig heart lactic dehydrogenase

Lactic dehydrogenase from pig heart can be reversibly dissociated at hydrostatic pressures above 1000 bar. The breakdown of the native quaternary structure occurs at lower pressures compared to the isoenzyme from pig, skeletal muscle. As shown by hybridization experiments of the two isoenzymes the final product of dissociation is the homogeneous monomer. Fluorescence emission spectra of the monomeric enzyme at elevated pressure are characterized by a decrease in fluorescence intensity without any red shift, indicating that no significant unfolding occurs upon high-pressure dissociation. The spectral changes are comparable to those observed after acid dissociation. The amount and rate of deactivation depend on pressure and on the conditions of the solvent. The presence of various anions (Cl^?, SO^2?₄. HPO₄^2?) has no effect on the stability of ihe enzyme towards pressure. High-pressure denaturation (as monitored by intrinsic protein fluorescence), and deactivalion (measured immediately after decompression) run parallel; the pressure dependence of their first-order rate constants is characterized by an activation volume ΔV^≠_Dc = ?140 = 10 cm³/mol. As taken from the yield of reconstitution, dissociation, denaturation and deactivation are found to be fully reversible provided the pressure does not exceed a limiting value (p = 1000 bar in Tris. pH 7.6: 24 h incubation at 20°C). After extended incubation beyond the limiting, pressure of 1000 bar. “irreversible high-pressure denaturation” occurs which is accompanied bv partial aggregation after decompression. The coenzyme, NAD⁺ stabilizes the native tetramer shifting the dissociation equilibrium to higher pressures. The overall dissociation-association reaction can be quantitatively described by a consecutive dissociation/unfolding mechanism N?4 M^'?4 M^☆ (where N is the native tetramer. and M^' and M^☆ two different conformations of the monomer). The reaction volume of the dissociation reaction N?4 M^' is found to be ΔV_Diss = ?360 = 30 cm³/mol: as indicated by the pressure dependence of the yield of reconstitution, the reaction volume of the equilibrium M^'?M^XXX is also negative.     

Extrajugular pathways of human cerebral venous blood drainage assessed by duplex ultrasound.

Cerebral venous drainage in humans is thought to be ensured mainly via the internal jugular veins (IJVs). However, anatomic, angiographic, and ultrasound studies suggest that the vertebral venous system serves as an important alternative drainage route. We assessed venous blood volume flow in vertebral veins (VVs) and IJVs of 12 healthy volunteers using duplex ultrasound. Measurements were performed at rest and during a transient bilateral IJV and a circular neck compression. Total venous blood volume flow at rest was 766 +/- 226 ml/min (IJVs: 720 +/- 232, VVs: 47 +/- 33 ml/min). During bilateral IJV compression, VV flow increased to 128 +/- 64 ml/min. Circular neck compression, causing an additional deep cervical vein obstruction, led to a further rise in VV volume flow (186 +/- 70 ml/min). As the observed flow increase did not compensate for IJV flow cessation, other parts of the vertebral venous system, like the intraspinal epidural veins and the deep cervical veins, have to be considered as additional alternative drainage pathways.     

The cytaster,a colchicine-sensitive migration organelle of cleavage nuclei in an insect egg

Time-lapse analyses of nuclear multiplication in the eggs of the gall midge Wachtliella persicariae L., documented in film D 1235 (available from the IWF, Göttingen), give evidence of a special migration organelle of cleavage nuclei. Each of these “migration cytasters” represents one greatly enlarged polar cytaster of the mitotic apparatus, which is connected to one nucleus. From the films it can be concluded that the astral rays temporarily adhere to peripheral egg structures and exert tractive forces toward the cytaster center. These forces combine and pull the accompanying daughter nucleus through the ooplasm after each mitosis. This “active” mode of migration, which is accompanied by extensive polarized transport of yolk particles toward the cytaster center, enables the energids (= cleavage nucleus and its associated island of cytoplasm) to move relative to the surrounding ooplasm. In addition, there is a “passive” mode of nuclear migration: The energids are moved by means of plasmic flows, thereby maintaining their position in relation to the surrounding ooplasm. Electron microscopic studies show solitary microtubules running radially toward the cytaster center. As a result of colchicine injection (1) the microtubules disintegrate, (2) the polarized transport of yolk particles cases, (3) the active nuclear migration stops and the nuclei are only passively moved by rhythmic ooplasmic flows. This inhibition of active nuclear migration gives further evidence that microtubules take an essential part in it. Control experiments with lumicolchicine show no effect on nuclear migration. Conversely, under the influence of cytochalasin B active nuclear migration is continued, while the ooplasmic flows are inhibited. Thus the mechanisms of active and passive nuclear migration can work independently of each other. The generation of tractive forces along the astral rays is discussed with respect to current models of spindle function.     

Laccase-induced HBT-grafting to milled beech wood reduces unspecific protein adsorption

Lignocellulosic biomass is a ubiquitous and renewable feedstock for the production of platform chemicals and biofuels. Typically, this recalcitrant biomass is pretreated by physico-chemical techniques causing disintegration and delignification. An additional treatment with laccase-mediator-systems (LMS) has been found to further improve the subsequent enzymatic cellulose hydrolysis. The aim of this study was to investigate the impact of different LMS on the glucose yield of a subsequent hydrolysis of treated beech wood and to elucidate the underlying effect of LMS treatment. The mediators 2,2′-azino-bis-3-ethylbenzothiazoline-6-sulphonic acid (ABTS), 1-hydroxybenzotriazol (HBT) and syringaldehyde were evaluated, but an enhancing effect of LMS treatment on beech wood hydrolysis was only found for HBT. In mass spectrometry analysis of the acid hydrolysate of LMS-treated samples, the mediator HBT could be found in the lignin samples, suggesting a grafting reaction. The fluorescent protein mCherry was used as a reporter for unspecific protein adsorption to biomass samples. LMS treatment with HBT reduced the unspecific adsorption of mCherry to raw beech wood by about 50%, suggesting that the HBT grafting to beech wood lignin decreased the unproductive cellulase binding. In summary, the reduction of unspecific protein adsorption by biomass surface modification with laccase-HBT treatment is proposed to be the underlying mechanism for increased cellulose conversion.     

Impacts of air pollution and climate change on forest ecosystems--emerging research needs

Outcomes from the 22nd meeting for Specialists in Air Pollution Effects on Forest Ecosystems "Forests under Anthropogenic Pressure--Effects of Air Pollution, Climate Change and Urban Development", September 10-16, 2006, Riverside, CA, are summarized. Tropospheric or ground-level ozone (O3) is still the phytotoxic air pollutant of major interest. Challenging issues are how to make O3 standards or critical levels more biologically based and at the same time practical for wide use; quantification of plant detoxification processes in flux modeling; inclusion of multiple environmental stresses in critical load determinations; new concept development for nitrogen saturation; interactions between air pollution, climate, and forest pests; effects of forest fire on air quality; the capacity of forests to sequester carbon under changing climatic conditions and coexposure to elevated levels of air pollutants; enhanced linkage between molecular biology, biochemistry, physiology, and morphological traits.