Endothelial mitochondria--a novel target for pharmacology of endothelial dysfunction

Vascular endothelium the inside layer of the cardiovascular system is presently looked upon as an important paracrine, autocrine and endocrine organ that determines the health of the cardiovascular system. In fact, healthy endothelium is essential for homeostasis of cardiovascular system, while endothelial dyfunction leads to cardiovascular diseases including atherosclerosis, diabetes and heart failure. Endothelial dysfunction is tightly linked to the overproduction of reactive oxygen species, development of oxidant stress and inflammatory response of endothelium. Mitochondria of the vascular endothelium seem to be an important player in these processes. In contrast to numerous cell types, synthesis of ATP in endothelium occurs in major part via a glycolytic pathway and endothelium seem to be relatively independent of the mitochondrial pathway of energy supply. However, as evident from recent studies, mitochondrial pathways of free radicals production tighly linked to mitochondrial and cytosol changes in the ion homeostasis play an important role in the regulation of endothelial inflammatory response, in the development of oxidative stress and apoptosis of vascular endothelium. Therefore, endothelial mitochondria appears critical in the regulation of endothelial functions and represent a novel target in pharmacology of endothelial dysfunction in cardiovascular diseases.     

The mutagenicity and DNA-damaging activity of cyclic aliphatic sulfuric acid esters.

The cyclic aliphatic sulfuric acid esters 1,2-ethylene sulfate (ESF), 1,3-propylene sulfate (PSF) and 1,3-butylene sulfate (BSF) have been tested for their mutagenic and DNA-damaging activity. Mutagenicity of the compounds was established with his-auxotrophic indicator strains of Salmonella typhimurium using the in vitro plate test and the host-mediated assay technique with mice as host animals. The DNA-damaging activity was tested in a repair test with Proteus mirabilis mutants defective in DNA repair.In the repair test with a set of P. mirabilis strains (PG713 hcr^?rec^?: PG273 hcr⁺rec⁺) PSF and BSF showed a preferential growth inhibition of the repair-defective strain suggesting DNA-damaging activity of these chemicals. No such activity was found for ESF using the same concentrations of 5 and 15 μmol/plate.All cyclic sulfates revert the tester strain TA1535 of S. typhimurium in vitro indicating their ability to induce base substitutions. Compared with the reference compounds dimethyl sulfate (DMS), diethyl sulfate (DES), 1,3-propane sulfone (PPS) and 1,4-butane sulfone (BTS) the mutagenic activity in the plate test can be described as follows: PPS > PSF > BSF > BTS > ESF > DES > DMS.Dose-response studies in the host-mediated assay with tester strain TA1950 of S. typhimurium as genetic indicator system revealed a linear dosedependency of mutagenic activity. For PPS and PSF the lowest effective dose (LED) has been established as 10 μmol/kg. The LED for BSF and BTS was 50 μmol/kg, DMS and DES were mutagenic in doses of 2500 μmol/kg, while ESF was only weakly mutagenic with a LED of 5000 μmol/kg.The dose-response studies in the host-mediated assay and the results obtained in the in vitro spot test demonstrate similarities in the mutagenic action of the cyclic sulfates PSF and BSF and the respective sulfones, while the stronger alkylating compound ESF was a weak mutagen both in vitro and in vivo.     

Biomineralization of gold by Mucor plumbeus: The progress in understanding the mechanism of nanoparticles’ formation

This contribution describes the deposition of gold nanoparticles by microbial reduction of Au(III) ions using the mycelium of Mucor plumbeus. Biosorption as the major mechanism of Au(III) ions binding by the fungal cells and the reduction of them to the form of Au(0) on/in the cell wall, followed by the transportation of the synthesized gold nanoparticles to the cytoplasm, is postulated. The probable mechanism behind the reduction of Au(III) ions is discussed, leading to the conclusion that this process is nonenzymatic one. Chitosan of the fungal cell wall is most likely to be the major molecule involved in biomineralization of gold by the mycelium of M. plumbeus. Separation of gold nanoparticles from the cells has been carried out by the ultrasonic disintegration and the obtained nanostructures were characterized by UV‐vis spectroscopy and transmission electron micrograph analysis. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1381–1392, 2017     

Nuclear and mitochondrial alterations in amebae exposed to ethidium bromide

Cultures of Amoeba proteus were exposed to ethidium bromide at concentrations ranging between 5 and 100 μg/ml for periods of up to 1 week. Samples of treated and control cells were prepared at intervals for electron microscopy. The main ultrastructural alterations were in nucleoli and in mitochondria. The nucleoli of treated cells increased in density and became spherical with more sharply defined margins than those of normal amebae. Many nucleoli contained electron-lucent regions or nucleolar vacuoles of varying size. The chromatin was unusually condensed in some amebae. Mitochondria developed a central electron-lucent region and accumulated a dense material in the matrix. Some cristae were abnormally dilated. The nuclear alterations occurred at least as early as the mitochondrial changes and were present even in cells exposed to the lower concentrations of inhibitor, in which mitochondrial changes were minimal.     

Evaluation of a vermicompost and leachates on <i>Solidago x hybrida</i> and organic carbon mineralization under aerobic incubations

In the floriculture region of Tenancingo in the State of Mexico, the application of stabilized organic matter, such as vermicompost and leachates, contributes to improve the quality of the soil and plant nutrition. However, it is important to know the chemical composition of a vermicompost and the mineralization process. This is because the amount and speed of nutrient release which will be available to the crop will depend on that knowledge. The objective of the study was to evaluate the effect of the application of a vermicompost and leachates on various quantitative variables of Solidago x hybrid, and the mineralization of organic carbon under aerobic incubations. Vermicompost (74 and 36 g/kg soil), leachates (5 and 10 L/kg soil), 0.33 g/kg soil of chemical fertilizer Ca (NO₃)₂, and not treated soil (control) were applied under greenhouse conditions to evaluate their effects on plant growth variables. Mixtures of 100 g of soil with vermicompost and leachates were made in the laboratory which were incubated during 9 weeks to obtain the potentially mineralizable organic carbon (Corg PM) and the rate of mineralization (k) after adjusting an exponential model. In the greenhouse experiment there were no statistical differences after applying vermicompost and leachates on the quantitative variables (number of stems per plant, diameter of the panicle, fresh weight, plant length and stem diameter) with respect to the control (p>0.05). The effect among the applied doses was evident only for variables such as fresh weight, panicle length and stem diameter with respect to the control. In incubated soils, k values ranged between 0.209-0.325 C mg/kg soil/week. Only with the application of leachates in high doses two pools of organic matter were shown: one soluble labile (102.9 mg/kg soil) and the other hydrolysable (819 mg/kg soil). The soluble, labile fraction favored nutrient availability immediately after its application to the soil. However, a single pool of hydrolysable organic C (987-1074 mg/kg soil) was found when vermicompost was applied. It was associated with a release of organic matter during crop development, and to a possible stimulation of microbial activity. High values of electrical conductivity in vermicompost and leachates (8.2-11.7 mS/m) suggest a moderate application of both products.     

Modelling of enzyme hydrolysis of maltose in a single pellet of immobilized biocatalyst

The reversible hydrolysis of maltose to glucose by immobilized glucoamylase entrapped in spherical solid particles is studied theoretically. For this purpose a known kinetic model taking into account these reversible reactions and the competitive synthesis of iso-maltose was adopted. The mass transfer limitations in the bulk liquid and in the pores of the particles containing the enzyme are considered, using Fick's law. On the basis of mathematical modelling the optimum conditions for biocatalyst performance are established. An appropriate combination of particle size and initial substrate concentration may lead to reduction of undesirable mass transfer resistance and therefore product inhibition and to an improved selectivity of the biocatalyst with respect of glucose formation.List of Symbols C _i kmoles/m³ current concentration ofi-th component along the radius - C _oi kmoles/m³ bulk concentration ofi-th component - C _i ^* kmoles/m³ concentrations ofi-th component on the pellet surface - D _si ,D _i m²/s internal and molecular diffusion coefficient ofi-th component - W _M kmoles/m³·s reaction rate of maltose hydrolysis - W _IM kmoles/m³·s reaction rate of iso-maltose formation - W _G kmoles/m³·s reaction rate of glucose production - R ₀ m pellet radius - r m current radius of the pellet - t s time coordinate - r ₀ ratio of the time step to the square of the radial coordinate - Re Reynolds number =w·R/v - Sc Schmidt number =v/D - Bi Biot number = R/D - A _j ,B, C _j coefficients in the system of linear equations, Eq. (8) - X _i dimensionless degree of transformation - NR number of independent reactions - N number of division sections of the pellet radius - G kmoles/m³ concentration of glucose - M kmoles/m³ concentration of maltose - IM kmoles/m³ concentration of isomaltose - K _m kmoles/m³ Michaelis constant - V _max kmoles/m³·s maximum reaction rate in Eq. (6) - K _i kmoles/m³ inhibition constant - K _1eq ,K _2eq equilibrium constants in Eq. (6) - , h steps along the time and radial coordinate in the pellet - m/s mass transfer coefficient - dimensionless radius of the pellet - computation accuracy Indices i number of reaction component - j index along the radius of the pellet - k index along the time coordinate This work was accomplished with thanks to the financial support of the Bulgarian National Fund for Scientific Investigations —Grant No. MU-1-BE/93.     

Using common mycorrhizal networks for controlled inoculation of Quercus spp. with Tuber melanosporum: the nurse plant method

The high cost and restricted availability of black truffle spore inoculum for controlled mycorrhiza formation of host trees produced for truffle orchards worldwide encourage the search for more efficient and sustainable inoculation methods that can be applied globally. In this study, we evaluated the potential of the nurse plant method for the controlled inoculation of Quercus cerris and Quercus robur with Tuber melanosporum by mycorrhizal networks in pot cultures. Pine bark compost, adjusted to pH?7.8 by liming, was used as substrate for all assays. Initially, Q. robur seedlings were inoculated with truffle spores and cultured for 12 months. After this period, the plants presenting 74 % mycorrhizal fine roots were transferred to larger containers. Nurse plants were used for two treatments of two different nursling species: five sterilized acorns or five 45-day-old, axenically grown Q. robur or Q. cerris seedlings, planted in containers around the nurse plant. After 6 months, colonized nursling plant root tips showed that mycorrhiza formation by T. melanosporum was higher than 45 % in the seedlings tested, with the most successful nursling combination being Q. cerris seedlings, reaching 81 % colonization. Bulk identification of T. melanosporum mycorrhizae was based on morphological and anatomical features and confirmed by sequencing of the internal transcribed spacer region of the ribosomal DNA of selected root tips. Our results show that the nurse plant method yields attractive rates of mycorrhiza formation by the Périgord black truffle and suggest that establishing and maintaining common mycorrhizal networks in pot cultures enables sustained use of the initial spore inoculum.     

Scale-up of stirring as foam disruption (SAFD) to industrial scale

Foam disruption by agitation—the stirring as foam disruption (SAFD) technique—was scaled up to pilot and production scale using Rushton turbines and an up-pumping hydrofoil impeller, the Scaba 3SHP1. The dominating mechanism behind SAFD—foam entrainment—was also demonstrated at production scale. The mechanistic model for SAFD defines a fictitious liquid velocity generated by the (upper) impeller near the dispersion surface, which is correlated with complete foam disruption. This model proved to be scalable, thus enabling the model to be used for the design of SAFD applications. Axial upward pumping impellers appeared to be more effective with respect to SAFD than Rushton turbines, as demonstrated by retrofitting a 12,000 l bioreactor, i.e. the triple Rushton configuration was compared with a mixed impeller configuration from Scaba with a 20% lower ungassed power draw. The retrofitted impeller configuration allowed 10% more broth without risking excessive foaming. In this way a substantial increase in the volumetric productivity of the bioreactor was achieved. Design recommendations for the application of SAFD are given in this paper. Using these recommendations for the design of a 30,000 l scale bioreactor, almost foamless Escherichia coli fermentations were realised. Electronic Publication     

Dynamic fuzzy model based predictive controller for a biochemical reactor

The kinetics of bioreactions often involve some uncertainties and the dynamics of the process vary during the course of fermentation. For such processes, conventional control schemes may not provide satisfactory control performance and demands extra effort to design advanced control schemes. In this study, a dynamic fuzzy model based predictive controller (DFMBPC) is presented for the control of a biochemical reactor. The DFMBPC incorporates an adaptive fuzzy modeling framework into a model based predictive control scheme to derive analytical controller output. The DFMBPC has the flexibility to opt with various types of fuzzy models whose choice also lead to improve the control performance. The performance of DFMBPC is evaluated by comparing with a fuzzy model based predictive controller (FMBPC) with no model adaptation and a conventional PI controller. The results show that DFMBPC provides better performance for tracking setpoint changes and rejecting unmeasured disturbances in the biochemical reactor.