A kinetic study of D-glucose oxidation by bromine in aqueous solutions

The kinetics of the oxidation of D-glucose to D-gluconic acid by bromine in aqueous solution were studied using potentiometric techniques and theoretical considerations of complex bromine-bromide-pH equilibria. The pH has a strong influence on reaction rate. At pH < 8 the reaction is very slow, while in the pH range pH 8-9.5 the reaction is sufficiently fast and seems optimal for the reaction. The proposed active species at that pH region is hypobromous acid. At pH > 9.5, the reaction is further accelerated due to the formation of hypobromite. The proposed kinetics expression for gluconic acid formation, based on the determined kinetic parameters at pH 9.24, is of the form dc(GA)/dt = 160c(2)(G)c(o)(HOBr)c(o)(H(+)c(o)(Br)     

Molecular, cellular, and antigen requirements for development of age-associated T cell clonal expansions in vivo

T cell aging manifests itself both at the cellular (cell-autonomous defects in signaling) and at the population (age-related dysregulation of T cell homeostasis) levels. A prominent contributor to the latter is the appearance of T cell clonal expansions (TCE), with a potential to impair immune defense. In this study, we investigated molecular, cellular, and Ag requirements for TCE development. Of the mutant mice tested, old animals lacking MHC class I exhibited 7-fold fewer TCE than controls, with a 7-fold reduction in TCE. By contrast, animals lacking only one of the MHC class I molecules (Kb or Db), or IL-7R, or devoid of T cell renewal via adult thymectomy, all exhibited significant increases in TCE incidence. This increase directly correlated to lymphopenia, increased CD8 T cell turnover and an accumulation of memory-phenotype T cells. These data suggested that homeostatic cell division in the CD8 compartment enhances the formation of TCE. Repeated immunization with peptide/adjuvant did not result in an increase in Ag-specific TCE; however, adjuvant alone increased TCE incidence. In these experiments, therefore, nonspecific and/or homeostatic proliferation was more efficient in generating TCE in mice than repeated Ag-driven stimulation, suggesting that many, if not most, TCE in specific pathogen-free laboratory mice may be Ag-independent.     

Regeneration of interspecific somatic hybrids between Helianthus annuus L. and Helianthus maximiliani (Schrader) via protoplast electrofusion

Helianthus maximiliani is one of the wild Helianthus species with the genes for resistance to many pathogens including Sclerotinia sclerotiorum. Unfortunately, a transfer of disease resistance genes from this species into the cultivated sunflower is limited by its poor crossability with the cultivated sunflower and sterility of interspecific hybrids. To overcome this problem, mesophyll protoplasts of Sclerotinia sclerotiorum-resistant clone of H. maximiliani were electrically fused with etiolated hypocotyl protoplasts of the cultivated sunflower inbred line PH-BC₁-91A. Fusion products were embedded in agarose droplets and subjected to different regeneration protocols. Developed microcalluses were released from the agarose and transferred into solid media. Shoot regeneration was achieved by culture of calluses on regeneration medium containing 2.2 mg l⁻¹ BAP and 0.01 mg l⁻¹ NAA after the treatment with a high concentration of 2,4 D for a limited period of time. A morphological and RAPD analysis confirmed a hybrid nature of the regenerated plants.     

Intellectual functioning and behavioral disorders

The paper discusses areas of behavioral functioning of children with intellectual disability, such as behavior with or without hyperactivity. The study covered 124 children with intellectual disability attending elementary schools in Belgrade. The Conners Rating Scale was used, and the areas of behavior in the classroom, participation in the group and attitude towards authority were covered. The results of our study suggest the presence of disorders in behavior and social-emotional functioning ranging from 11.2 to 40.4%. We have highlighted the importance of the use of multimodal approach and method of reeducation of psychomotor activity in rehabilitation of the studied children.     

Planar Cell Polarity Signaling: The Developing Cell��s Compass

Cells of many tissues acquire cellular asymmetry to execute their physiologic functions. The planar cell polarity system, first characterized in Drosophila, is important for many of these events. Studies in Drosophila suggest that an upstream system breaks cellular symmetry by converting tissue gradients to subcellular asymmetry, whereas a downstream system amplifies subcellular asymmetry and communicates polarity between cells. In this review, we discuss apparent similarities and differences in the mechanism that controls PCP as it has been adapted to a broad variety of morphological cellular asymmetries in various organisms.The terms tissue polarity and planar cell polarity (PCP) were coined to describe the coordinated orientation of cells and cellular structures along an axis within the plane of an epithelial surface. Polarized cellular orientation and migration controlled by PCP is critical for multiple developmental processes, and defects underlie developmental anomalies. Vertebrate PCP mutations produce problems, including neural tube, cardiac, and renal developmental defects and misorientation of hair follicles and inner ear hair cells (Wang and Nathans 2007; Simons and Mlodzik 2008). PCP may be involved in the invasive and metastatic properties of carcinomas (Jessen 2009). Recently, many PCP-related phenotypes have been observed in association with mutations affecting primary cilia, thus connecting primary cilia to the PCP process (Singla and Reiter 2006; see Hirokawa et al. 2009). Therefore, dissecting the mechanisms of PCP signaling is of considerable interest.PCP was initially characterized in Drosophila through genetic studies of PCP mutants, which led to the proposal of a PCP signaling pathway (Wong and Adler 1993; reviewed in Adler 1992). According to newer models, epithelial polarity is established by the combination of a global directional cue distributed throughout the epithelium and cellular factors that interpret this cue to align cells with each other and the axis of polarity (Tree et al. 2002a; Zallen 2007). Once molecular polarity is determined, cell-type-specific downstream proteins affect morphological polarity. PCP components are highly conserved from flies to vertebrates, and the PCP pathway is now known to be active in many processes in polarized cells and tissues not limited to epithelia. PCP components are involved in oriented cell division, acquisition of asymmetric cellular morphology, and directional cell migration, each process representing a vectorial behavior. Although the mechanism of PCP signaling in most cases is just beginning to be understood, there appear to be diverse mechanisms sharing common themes. This mechanistic diversity may be demanded by the varying PCP-dependent morphological processes, and evidently arose by divergence from a common ancestral mechanism.Here, we describe our current understanding of how the PCP pathway functions in diverse processes, highlighting both common themes and diverging mechanisms. The obvious medical importance of the PCP pathway (see, for example, Kibar et al. 2007), and the growing interest in primary cilia will surely stimulate rapid gains in our knowledge of PCP in multiple cellular contexts.     

Emerging new paradigms for ABCG transporters

Every cell is separated from its external environment by a lipid membrane. Survival depends on the regulated and selective transport of nutrients, waste products and regulatory molecules across these membranes, a process that is often mediated by integral membrane proteins. The largest and most diverse of these membrane transport systems is the ATP binding cassette (ABC) family of membrane transport proteins. The ABC family is a large evolutionary conserved family of transmembrane proteins (> 250 members) present in all phyla, from bacteria to Homo sapiens, which require energy in the form of ATP hydrolysis to transport substrates against concentration gradients. In prokaryotes the majority of ABC transporters are involved in the transport of nutrients and other macromolecules into the cell. In eukaryotes, with the exception of the cystic fibrosis transmembrane conductance regulator (CFTR/ABCC7), ABC transporters mobilize substrates from the cytoplasm out of the cell or into specific intracellular organelles. This review focuses on the members of the ABCG subfamily of transporters, which are conserved through evolution in multiple taxa. As discussed below, these proteins participate in multiple cellular homeostatic processes, and functional mutations in some of them have clinical relevance in humans.     

Characterisation of N-glycans bound to IGFBP-3 in sera from healthy adults

Human IGFBP-3 contains three potential N-linked glycosylation sites. Published data concerning the type and saccharide composition of the N-glycans is scarce. The aim of this study was to characterise N-glycans covalently attached to IGFBP-3 from sera of healthy adults (men and women). In order to do that a panel of eight lectins covering broad saccharide specificity was used: agarose-immobilised SNA (Sambucus nigra agglutinin), Con A (lectin from Canavalia ensiformis), RCA I (Ricinus communis agglutinin I), PHA-E (Phaseolus vulgaris erythroagglutinin), PHA-L (P. vulgaris leukoagglutinin), succinylated WGA (wheat germ agglutinin), ECL (Erythrina cristagalli lectin) and UEA (Ulex europaeus agglutinin). IGFBP-3 interacted with SNA, Con A, RCA I, PHA-E and, to a much lesser extent, with PHA-L. These results indicate that human IGFBP-3 bears mostly biantennary complex type N-glycans with a very high content of α-2,6-linked Sia at their termini. Hybrid type and high-mannose type N-glycans are present, as well as a bisecting GlcNAc residue, which may be core fucosylated. N-glycosylation of IGFBP-3 follows the N-glycosylation pattern of major serum proteins. This study represents a ground for the future research of glycosylation pattern of IGFBP-3 from the circulation of men and women diagnosed with different illnesses.     

Acute and/or chronic stress models modulate CuZnSOD and MnSOD protein expression in rat liver

Cellular protection against oxidative stress is afforded by the enzyme superoxide dismutase (SOD). In this study, the protein levels of copper–zinc SOD (CuZnSOD) in the cytosolic and nuclear fraction, manganese SOD (MnSOD) in the mitochondrial, and cytosolic fraction and cytochrome c (cyt c) in the liver of male rats exposed to 2 h of acute immobilization (IM) or Cold stress, 21 days chronic isolation or their combinations (chronic/acute stress) were examined. The serum corticosterone (CORT) level was measured, as an indicator of stress stimuli. Both acute stressors with elevated CORT levels caused a decrease of mitochondrial MnSOD, while acute IM resulted in redistribution of the CuZnSOD protein level between the cytosolic and nuclear fraction. Chronic isolation, during which the CORT level was close to control value, resulted in an increase of cytosolic CuZnSOD, whereas a decrease of MnSOD in mitochondrial and its corresponding increase in cytosol fraction was found. In both combined stress regimes, an increase of the CuZnSOD and MnSOD levels in the cytosolic fraction was recorded whereby increase of the CORT level was observed only in the chronic isolation followed by acute IM. The data indicate that acute and/or chronic stress models have different degrees of influence on serum CORT and SOD subcellular protein levels. Increased cytosolic CuZnSOD protein level under chronic isolation suggests that state of oxidative stress may also exist under CORT level similar to the basal value. The presence of MnSOD and cyt c in the cytosolic fraction could serve as useful parameters for mitochondrial dysfunction.     

HIF-1alpha response to hypoxia is functionally separated from the glucocorticoid stress response in the in vitro regenerating human skeletal muscle

Injury of skeletal muscle is followed by muscle regeneration in which new muscle tissue is formed from the proliferating mononuclear myoblasts, and by systemic response to stress that exposes proliferating myoblasts to increased glucocorticoid (GC) concentration. Because of its various causes, hypoxia is a frequent condition affecting skeletal muscle, and therefore both processes, which importantly determine the outcome of the injury, often proceed under hypoxic conditions. It is therefore important to identify and characterize in proliferating human myoblasts: 1) response to hypoxia which is generally organized by hypoxia-inducible factor-1α (HIF-1α); 2) response to GCs which is mediated through the isoforms of glucocorticoid receptors (GRs) and 11β-hydroxysteroid dehydrogenases (11β-HSDs), and 3) the response to GCs under the hypoxic conditions and the influence of this combination on the factors controlling myoblast proliferation. Using real-time PCR, Western blotting, and HIF-1α small-interfering RNA silencing, we demonstrated that cultured human myoblasts possess both, the HIF-1α-based response to hypoxia, and the GC response system composed of GRα and types 1 and 2 11β-HSDs. However, using combined dexamethasone and hypoxia treatments, we demonstrated that these two systems operate practically without mutual interactions. A seemingly surprising separation of the two systems that both organize response to hypoxic stress can be explained on the evolutionary basis: the phylogenetically older HIF-1α response is a protection at the cellular level, whereas the GC stress response protects the organism as a whole. This necessitates actions, like downregulation of IL-6 secretion and vascular endothelial growth factor, that might not be of direct benefit for the affected myoblasts.     

Brown-Vialetto-Van Laere Syndrome, a Ponto-Bulbar Palsy with Deafness, Is Caused by Mutations in C20orf54

Brown-Vialetto-Van Laere syndrome is a rare neurological disorder with a variable age at onset and clinical course. The key features are progressive ponto-bulbar palsy and bilateral sensorineural deafness. A complex neurological phenotype with a mixed picture of upper and lower motor neuron involvement reminiscent of amyotrophic lateral sclerosis evolves with disease progression. We identified a candidate gene, C20orf54, by studying a consanguineous family with multiple affected individuals and subsequently demonstrated that mutations in this gene were the cause of disease in other, unrelated families.