Rapid turnover of acetyl groups in the four core histones of simian virus 40 minichromosomes.

The four core histones (H2a, H2b, H3, and H4) bound to simian virus 40 minichromosomes isolated from infected cells contain rapidly labeled acetyl groups in internal positions of the histone polypeptide chain. Upon chase, these acetyl residues decay with a half-life of less than 15 min. The acetyl groups are incorporated in histones bound to mature chromosomes and not in newly synthesized histones bound to replicating viral chromosomes. The rate of acetate incorporation is not related to the degree of steady state acetylation of the individual viral or cellular histones. This rate is 4-fold higher for the viral chromatin than for its cellular counterpart isolated from the same nuclei. The possible role for histone acetylation in viral genome expression is discussed.     

Mapping the diatom redox-sensitive proteome provides insight into response to nitrogen stress in the marine environment

Diatoms are ubiquitous marine photosynthetic eukaryotes responsible for approximately 20% of global photosynthesis. Little is known about the redox-based mechanisms that mediate diatom sensing and acclimation to environmental stress. Here we used a quantitative mass spectrometry-based approach to elucidate the redox-sensitive signaling network (redoxome) mediating the response of diatoms to oxidative stress. We quantified the degree of oxidation of 3,845 cysteines in the Phaeodactylum tricornutum proteome and identified approximately 300 redox-sensitive proteins. Intriguingly, we found redox-sensitive thiols in numerous enzymes composing the nitrogen assimilation pathway and the recently discovered diatom urea cycle. In agreement with this finding, the flux from nitrate into glutamine and glutamate, measured by the incorporation of ¹⁵N, was strongly inhibited under oxidative stress conditions. Furthermore, by targeting the redox-sensitive GFP sensor to various subcellular localizations, we mapped organelle-specific oxidation patterns in response to variations in nitrogen quota and quality. We propose that redox regulation of nitrogen metabolism allows rapid metabolic plasticity to ensure cellular homeostasis, and thus is essential for the ecological success of diatoms in the marine ecosystem.Aerobic organisms produce reactive oxygen species (ROS) as a byproduct of oxygen-based metabolic pathways, such as photosynthesis, photorespiration, and oxidative phosphorylation (1). Perturbations in oxygenic metabolism under various stress conditions can induce oxidative stress from overproduction of ROS (2, 3). Because ROS are highly reactive forms of oxygenic metabolites, critical mechanisms for ROS detoxification have evolved consisting of ROS-scavenging enzymes and small molecules, including glutathione (GSH) (4). As the most abundant low molecular weight thiol antioxidant, GSH has critical roles in maintaining a proper cellular thiol–disulfide balance and in detoxifying H₂O₂ via the ascorbate–GSH cycle (5).Although classically ROS were considered toxic metabolic byproducts that ultimately lead to cell death, it is now recognized that ROS act as central secondary messengers involved in compartmentalized signaling networks (1, 6–8). Modulation of various cell processes by ROS signaling is mediated largely by posttranslational thiol oxidation, whereby their physical structure and biochemical activity are modified upon oxidation (9). Thus, the redox states of these proteins possess crucial information needed for cell acclimation to stress conditions (10, 11). The emergence of advanced redox proteomic approaches, such as the OxICAT method (12), has created new opportunities to identify redox-sensitive proteins (e.g., redoxome) on the system level and to quantify their precise level of oxidation on exposure to environmental stress conditions.Marine photosynthetic microorganisms (phytoplankton) are the basis of marine food webs. Despite the fact that their biomass represents only approximately 0.2% of the photosynthetic biomass on earth, they are responsible for nearly 50% of the annual global carbon-based photosynthesis and greatly influence the global biogeochemical carbon cycle (13). This high ratio of productivity to biomass, reflected in high turnover rates, makes phytoplankton highly responsive to climate change. Phytoplankton can grow rapidly and form massive blooms that stretch over hundreds of kilometers in the oceans and are regulated by such environmental factors as nutrient availability and biotic interactions with grazers and viruses.Diatoms are a highly diverse clade of phytoplankton, responsible for roughly 20% of global primary productivity (14). Consequently, diatoms play a central role in the biogeochemical cycling of important nutrients, including carbon, nitrogen, and silica, which constitute part of their ornate cell wall. As members of the eukaryotic group known as stramenopiles (or heterokonts), diatoms are derived from a secondary endosymbiotic event involving red and green algae engulfed within an ancestral protest (15).The unique multilineage content of diatom genomes reveals a melting pot of biochemical characteristics that resemble bacterial, plant, and animal traits, including the integration of a complete urea cycle, fatty acid oxidation in the mitochondria, and plant C4-like related pathways (16, 17). During bloom succession, phytoplankton cells are subjected to diverse environmental stress conditions that lead to ROS production, such as allelopathic interactions (18), CO₂ availability (19, 20), UV exposure (21), iron limitation (22), and viral infection (23). Recently reported evidence suggests that diatoms possess a surveillance system based on the induction of ROS that have been implicated in response to various environmental stresses (22, 24). Nevertheless, very little is known about cell signaling processes in marine phytoplankton and their potential role in acclimation to rapid fluctuations in the chemophysical gradients in the marine environment (25).Using a mass spectrometry-based approach, we examined the diatom redoxome and quantified its degree of oxidation under oxidative stress conditions. The wealth of recently identified redox-sensitive proteins participating in various cellular functions suggests a fundamental role of redox regulation in diatom biology. We mapped the redox-sensitive enzymes into a metabolic network and evaluated their role in the adjustment of metabolic flux under variable environmental conditions. We further explored the redox sensitivity of the primary nitrogen-assimilating pathway and demonstrated the role of compartmentalized redox regulation in cells under nitrogen stress conditions using a redox-sensitive GFP sensor targeted to specific subcellular localizations.     

Neuroimmunological function in parents of children suffering from cancer

The main aim of this study is to evaluate the relationship between depression and immunological function in parents of children with cancer. Thirty-two parents participated in the study. The parents completed the following assessments: a list of major stressful events in a Hemato-Oncology ward, beck depression inventory II (BDI-II), posttraumatic diagnostic scale (PDS) and quality of life (QOL) questionnaire. A single blood sample was drawn from parents for evaluation of cortisol levels and lymphocyte cell subgroups. The parents were divided into two groups: Those who suffered from depression as defined by BDI-II cutoff score of 14 (depressed parents (DP), n = 7), and non-depressed parents (non-DP, n = 25). In parents of children with cancer the DP group had statistically significantly higher stressful event scores, dysfunction scores (from the PDS) and CD8 percentage compared to the non-DP group. QOL, CD4 percentage and CD4/CD8 ratio were significantly lower in the DP group. The BDI scores significantly positively correlated with events and dysfunctional scores, and significantly negatively correlated with QOL scores and CD4/CD8 ratio. High psychiatric morbidity was found in parents of children with cancer. The findings of altered immunity in DP provide further evidence that the physiological response to stress and depression may alter immune functions.     

Mid-term Results of Laparoscopic Sleeve Gastrectomy and Roux-en-Y Gastric Bypass in Adolescent Patients

The prevalence and severity of obesity in children and adolescents has been increasing in recent years at an unprecedented rate. Morbidly obese children will almost certainly develop severe comorbidities as they progress to adulthood, and bariatric surgery may provide the only alternative for achieving a healthy weight. The aim of this study was to assess the long-term outcomes and safety of laparoscopic sleeve gastrectomy (LSG) and Roux-en-Y gastric bypass (RYGB) as new treatment modalities for morbidly obese adolescents. We conducted a retrospective review of a prospectively collected database of all adolescent patients who underwent LSG and RYGB under IRB protocol at the Bariatric and Metabolic Institute in Cleveland Clinic Florida between 2002 and 2011. Patients were also contacted by phone, adhering to HIPAA regulations, and were asked to answer a survey. Eighteen adolescents had a bariatric procedure performed at this institution. The mean age was 17.5 years, the average weight was 293.1 lbs, and the average BMI was 47.2 kg/m². The mean follow-up period consisted of 55.2 months. The postoperative weight at 55 months follow-up was 188.4 lbs and average BMI was 30.1 kg/m². Fifteen of the patients were available for follow-up. Thirteen out of 16 (81 %) comorbidities in patients available for follow-up were in remission following rapid weight loss. The long-term follow-up and perioperative morbidity shown in this study suggest that LSG and LRYGB appear to be safe and effective operations in morbidly obese adolescents.     

Short‐term plasticity following motor sequence learning revealed by diffusion magnetic resonance imaging

Current noninvasive methods to detect structural plasticity in humans are mainly used to study long‐term changes. Diffusion magnetic resonance imaging (MRI) was recently proposed as a novel approach to reveal gray matter changes following spatial navigation learning and object‐location memory tasks. In the present work, we used diffusion MRI to investigate the short‐term neuroplasticity that accompanies motor sequence learning. Following a 45‐min training session in which participants learned to accurately play a short sequence on a piano keyboard, changes in diffusion properties were revealed mainly in motor system regions such as the premotor cortex and cerebellum. In a second learning session taking place immediately afterward, feedback was given on the timing of key pressing instead of accuracy, while participants continued to learn. This second session induced a different plasticity pattern, demonstrating the dynamic nature of learning‐induced plasticity, formerly thought to require months of training in order to be detectable. These results provide us with an important reminder that the brain is an extremely dynamic structure. Furthermore, diffusion MRI offers a novel measure to follow tissue plasticity particularly over short timescales, allowing new insights into the dynamics of structural brain plasticity.