Vascular endothelial growth factor (VEGF) +405 C/G polymorphism is associated with essential hypertension in a population from Tehran of Iran

Vascular endothelial growth factor (VEGF) has long been recognized as a hypotensive mediator. Little is known regarding the contribution of polymorphisms in VEGF gene to essential hypertension (EH), however. We aimed to investigate the association between +405 VEGF C/G single nucleotide polymorphism (SNP) and occurrence of EH in a sample of patients with diabetes. A study population of 474 subjects with diabetes of which 45.6% (216) had EH was enrolled in this study. Interviews and physical examinations were performed in a clinical setting. Subjects were matched in baseline anthropometric and biochemical characteristics except for total cholesterol. Genotyping of +405 VEGF C/G (rs2010963) SNP was carried out using polymerase chain reaction–restriction fragment length polymorphism. The allelic distribution of the sample did not violate Hardy–Weinberg equilibrium. Subjects with EH had a higher frequency of G allele (P = 0.005). Additionally, those with EH had a significantly higher frequency of GG genotype (P = 0.015). In multivariate logistic regression models controlling for possible confounders, having GG against CC genotype was associated with an odds ratio of 2.51 (95% CI: 1.44–4.38; P = 0.001). Moreover, presence of each G allele was linked to a 1.58-fold increase in risk of having EH (95% CI: 1.200–2.086; P = 0.001). In conclusion, +405 VEGF C/G SNP is associated with EH in patients with diabetes, suggesting presence of G allele and GG or CG genotype confer susceptibility towards EH.     

Investigation of saccadic eye movement effects on the fluid dynamic in the anterior chamber

The aqueous humor (AH) flow in the anterior chamber (AC) due to saccadic movements is investigated in this research. The continuity, Navier-Stokes and energy equations in 3D and unsteady forms are solved numerically and the saccadic motion was modeled by the dynamic mesh technique. Firstly, the numerical model was validated for the saccadic movement of a spherical cavity with analytic solutions and experimental data where excellent agreement was observed. Then, two types of periodic and realistic saccadic motions of the AC are simulated, whereby the flow field is computed for various saccade amplitudes and the results are reported for different times. The results show that the acting shear stress on the corneal endothelial cells from AH due to saccadic movements is much higher than that due to normal AH flow by buoyancy induced due to temperature gradient. This shear stress is higher on the central region of the cornea. The results also depict that eye saccade imposes a 3D complicated flow field in the AC consist of various vortex structures. Finally, the enchantment of heat transfer in the AC by AH mixing as a result of saccadic motion is investigated.     

Green Revolution Trees: Semidwarfism Transgenes Modify Gibberellins, Promote Root Growth, Enhance Morphological Diversity, and Reduce Competitiveness in Hybrid Poplar

Semidwarfism has been used extensively in row crops and horticulture to promote yield, reduce lodging, and improve harvest index, and it might have similar benefits for trees for short-rotation forestry or energy plantations, reclamation, phytoremediation, or other applications. We studied the effects of the dominant semidwarfism transgenes GA Insensitive (GAI) and Repressor of GAI-Like, which affect gibberellin (GA) action, and the GA catabolic gene, GA 2-oxidase, in nursery beds and in 2-year-old high-density stands of hybrid poplar (Populus tremula × Populus alba). Twenty-nine traits were analyzed, including measures of growth, morphology, and physiology. Endogenous GA levels were modified in most transgenic events; GA₂₀ and GA₈, in particular, had strong inverse associations with tree height. Nearly all measured traits varied significantly among genotypes, and several traits interacted with planting density, including aboveground biomass, root-shoot ratio, root fraction, branch angle, and crown depth. Semidwarfism promoted biomass allocation to roots over shoots and substantially increased rooting efficiency with most genes tested. The increased root proportion and increased leaf chlorophyll levels were associated with changes in leaf carbon isotope discrimination, indicating altered water use efficiency. Semidwarf trees had dramatically reduced growth when in direct competition with wild-type trees, supporting the hypothesis that semidwarfism genes could be effective tools to mitigate the spread of exotic, hybrid, and transgenic plants in wild and feral populations.Semidwarfism is a valuable trait in many crop species and agricultural environments. In cereal crops, it can result in decreased lodging, increased yield, and improved harvest index (Dalrymple, 1985; Hedden, 2003). Therefore, it was a critical foundation of the “Green Revolution” that resulted in large improvements of yield in wheat (Triticum aestivum) and rice (Oryza sativa; Hargrove and Cabanilla, 1979; Perovic et al., 2008). Semidwarfism has had substantial benefits for fruit tree production, where it enables earlier fruit bearing, higher yields, and easier harvests in orchards (Battisini and Battisini, 2005). Semidwarf woody species are also extensively used in ornamental horticulture, where they allow more compact forms to be fit into small areas around homes and on streets and reduce the need for pruning to avoid interference with structures and transmission lines (Busov et al., 2003).Although against the current orthodoxy of forest tree breeding, where height growth is emphasized, semidwarfism might also have benefits for wood and biomass production (Bradshaw and Strauss, 2001). Such trees could be useful if they were less prone to wind throw due to their shorter, stockier forms and expected greater allocation to roots. Reduced stature could also result in less bending and slanting of trunks in the face of wind and gravity on hillslopes and thus reduce the extent of reaction wood formation, which degrades the performance and value of solid wood and pulp products. Reduced height and increased allocation of growth to roots might enhance stress tolerance, soil nutrient uptake, bioremediation, and carbon sequestration.Semidwarfism can be achieved by the modification of several types of genes and physiological mechanisms, but the most prevalent and advanced forms in agriculture affect GAs or their signaling (for review, see Busov et al., 2008). GAs are endogenous plant hormones that influence several aspects of plant growth and development, including seed germination, leaf expansion, shoot growth, cell division, flower induction, and fruit development (Sun and Gubler, 2004; Fleet and Sun, 2005; Swain and Singh, 2005). With respect to shoot growth, the most obvious effect of GA is its promotion of stem elongation by stimulating both cell elongation and division (Marth et al., 1956). GA modification also has significant effects on plant biochemistry, changing the amounts and distribution of a wide variety of metabolites in shoots and roots (Rossetto et al., 2003; Chen et al., 2004; Busov et al., 2006).Little is known about how semidwarfism affects belowground growth. GA has been shown to play a controlling role in lateral root development (Gou et al., 2010), and GA and ethylene synergistically promote both the initiation and growth of adventitious roots (Osmont et al., 2007). In tomato (Solanum lycopersicum), isogenic GA-deficient mutants (gib) allocate more biomass to roots compared with shoots (Nagel et al., 2001). In poplar (Populus spp.), semidwarf transgenic plants grown in vitro had a lower shoot-to-root ratio, which was at least partly due to proliferation of lateral roots (Busov et al., 2006; Gou et al., 2010).As a domestication trait, semidwarfism has been proposed as a means for mitigating the spread of transgenic plants within and outside of crop environments (Al-Ahmad et al., 2005). The genetic dominance of most semidwarfism transgenes would cause reduced height growth in transgene-containing progeny, reducing their ability to compete for light. Moreover, because of the close linkage of the semidwarfism genes to other genes that were cointroduced on the same plasmid, they would also powerfully retard their spread or introgression, even in cases where the linked transgene would, on their own, impart a selective advantage. However, there have been very few plant species where this concept has been explicitly tested (Al-Ahmad and Gressel, 2006; Gressel and Valverde, 2009), and we know of no examples in woody or perennial plants.To study the effects of semidwarfism genes in a woody plant grown under field conditions, we inserted a number of dominant GA-modifying transgenes into hybrid poplar (Populus tremula × Populus alba), the widely recognized model woody plant for genomics and biotechnology (Herschbach and Kopriva, 2002; Brunner et al., 2004a; Tuskan et al., 2004). Most of the genes studied were overexpressed forms of GA 2-oxidase, GA-Insensitive (GAI), or Repressor of GAI-Like (RGL), all known to cause semidwarfism in other plant species. GA 2-oxidase is a major GA catabolic enzyme in plants, and GAI and RGL are negative regulators of the GA signal transduction pathway (Appleford et al., 2007; Busov et al., 2008). The transgenic trees were first analyzed in the greenhouse (Busov et al., 2006) and then assayed for their effect on height growth in a 2-year field trial (Zawaski et al., 2011), from which we selected 10 transgenic events that grew at approximately three-quarters the rate of wild-type trees. The goal was to select semidwarf trees whose phenotype was not so severe as to be irrelevant to possible crop uses but strong enough to give a clear phenotype in a field study. In this study, we analyzed changes in a number of morphological, physiological, and growth traits and investigated the prospect for semidwarfism to be used as a mitigation tool to reduce the frequency of spread of transgenic and exotic species.     

Expression of biologically active human clotting factor IX in Drosophila S2 cells: γ-carboxylation of a human vitamin K-dependent protein by the insect enzyme

The Drosophila γ-glutamyl carboxylase (dγC) has substrate recognition properties similar to that of the vertebrate γ-carboxylase (γC), and its carboxylated product yield, in vitro, was shown to be more than that obtained with the human enzyme. However, whether the Drosophila enzyme is able to γ-carboxylate the human vitamin K-dependent (VKD) proteins, such as the human coagulation factor IX (hFIX), as synthesized in cultured Drosophila cells was not known. To examine this possibility, the Drosophila Schnider (S2) cell line was transfected with a metallothionein promoter-regulated hFIX-expressing plasmid. After induction with copper ion, expression efficiency of the active hFIX was analyzed by performing enzyme-linked immunosorbent assey (ELISA) and coagulation test on the culture supernatant of the transfected S2 cells during 72 h of postinduction. In comparison with Chinese hamster ovary cell line, S2 cells showed higher (≈ 12-fold) expression level of the hFIX. The γ-carboxylation of the Drosophila-derived hFIX was confirmed by evaluation of the expressed protein, after being precipitated with barium citrate. The biological activity of the S2 cell-derived hFIX indicated the capability of S2 cells to fulfill the required γ-carboxylation of the expressed hFIX. Coexpression of the human γ-glutamyl carboxylases (hγC) was also shown to improve both expression and γ-carboxylation of the hFIX. This is the first in vivo data to describe the ability of the dγC to recognize the human-based propeptide as substrate, which is an essential step for production of biologically active γ-carboxylated VKD proteins.     

Computational simulation of internal bone remodelling around dental implants: a sensitivity analysis

This study aimed to predict the distribution of bone trabeculae, as a density change per unit time, around a dental implant based on applying a selected mathematical remodelling model. The apparent bone density change as a function of the mechanical stimulus was the base of the applied remodelling model that describes disuse and overload bone resorption. The simulation was tested in a finite element model of a screw-shaped dental implant in an idealised bone segment. The sensitivity of the simulation to different mechanical parameters was investigated; these included element edge length, boundary conditions, as well as direction and magnitude of the implant loads. The alteration in the mechanical parameters had a significant influence on density distribution and model stability, in particular at the cortical bone region. The remodelling model could succeed to achieve trabeculae-like structure around osseointegrated dental implants. The validation of this model to a real clinical case is required.     

Human endometrial stem cell neurogenesis in response to NGF and bFGF

The potential of cell therapy is promising in nerve regeneration, but is limited by ethical considerations about the proper and technically safe source of stem cells. We report the successful differentiation of human EnSCs (endometrial stem cells) as a rich source of renewable and safe progenitors into high-efficiency cholinergic neurons. The extracellular signals of NGF (nerve growth factor) and bFGF (basic fibroblast growth factor) could induce cholinergic neuron differentiation. ChAT (choline acetyltransferase), MAP2 (microtubule associated protein 2) and NF-l (neurofilament L) increased after administration of bFGF and NGF to the EnSC cultures. trkC and FGFR2 (fibroblast growth factor receptor 2), which belong to the NGF and bFGF receptors respectively, were determined in populations of EnSCs. NGF, bFGF and their combination differentially influenced human EnSCs high efficiency differentiation. By inducing cholinergic neurons from EnSCs in a chemically defined medium, we could produce human neural cells without resorting to primary culture of neurons. This in vitro method provides an unlimited source of human neural cells and facilitates clinical applications of EnSCs for neurological diseases.     

Functional beta-cell maturation is marked by an increased glucose threshold and by expression of urocortin 3

Insulin-expressing cells that have been differentiated from human pluripotent stem cells in vitro lack the glucose responsiveness characteristic of mature beta cells. Beta-cell maturation in mice was studied to find genetic markers that enable screens for factors that induce bona fide beta cells in vitro. We find that functional beta-cell maturation is marked by an increase in the glucose threshold for insulin secretion and by expression of the gene urocortin 3.