Captopril normalizes insulin signaling and insulin-regulated substrate metabolism in obese (ob/ob) mouse hearts

The goal of this study was to determine whether inhibiting the renin-angiotensin system would restore insulin signaling and normalize substrate use in hearts from obese ob/ob mice. Mice were treated for 4 wk with Captopril (4 mg/kg x d). Circulating levels of free fatty acids, triglycerides, and insulin were measured and glucose tolerance tests performed. Rates of palmitate oxidation and glycolysis, oxygen consumption, and cardiac power were determined in isolated working hearts in the presence and absence of insulin, along with levels of phosphorylation of Akt and AMP-activated protein kinase (AMPK). Captopril treatment did not correct the hyperinsulinemia or impaired glucose tolerance in ob/ob mice. Rates of fatty acid oxidation were increased and glycolysis decreased in ob/ob hearts, and insulin did not modulate substrate use in hearts of ob/ob mice and did not increase Akt phosphorylation. Captopril restored the ability of insulin to regulate fatty acid oxidation and glycolysis in hearts of ob/ob mice, possibly by increasing Akt phosphorylation. Moreover, AMPK phosphorylation, which was increased in hearts of ob/ob mice, was normalized by Captopril treatment, suggesting that in addition to restoring insulin sensitivity, Captopril treatment improved myocardial energetics. Thus, angiotensin-converting enzyme inhibitors restore the responsiveness of ob/ob mouse hearts to insulin and normalizes AMPK activity independently of effects on systemic metabolic homeostasis.     

Exercise‐Induced Ventricular Arrhythmias and Cardiovascular Death

Background: Exercise‐induced ventricular arrhythmias (EIVA) are frequently observed during exercise testing. However, the clinical guidelines do not specify their significance and so we examined this issue in our population. Methods: A retrospective analysis of prospectively collected data was performed on 5754 consecutive male veterans referred for exercise testing at two university‐affiliated Veterans Affairs Medical Centers. Exercise test responses were recorded and cardiovascular mortality was assessed after a mean follow‐up of 6 ± 4 years. EIVA were defined as frequent premature ventricular complexes (PVCs) constituting more than 10% of all ventricular depolarizations during any 30‐second ECG recording, or a run of three or more consecutive PVCs during the exercise test or recovery. Results: EIVA occurred in 426 patients (7.4%). There were 550 (10.6%) cardiovascular deaths during follow‐up. Seventy two (17%) patients with EIVA died of cardiovascular causes, whereas 478 (9.0%) of patients without EIVA died of cardiovascular causes (P < 0.001). Patients with EIVA had a higher prevalence of cardiovascular disease, resting PVCs, resting ST depression, and ischemia during exercise than patients without EIVA. In a Cox hazards model adjusted for age, cardiovascular disease, exercise‐induced ischemia, ECG abnormalities, exercise capacity and risk factors, EIVA was significantly associated with time to cardiovascular death. The combination of both resting PVCs and EIVA was associated with the highest hazard ratio. Conclusions: EIVA are independent predictors of cardiovascular mortality after adjusting for other clinical and exercise test variables; combination with resting PVCs carries the highest risk.     

Poststroke acute dysexecutive syndrome,a disorder resulting from minor stroke due to disruption of network dynamics

Stroke patients with small central nervous system infarcts often demonstrate an acute dysexecutive syndrome characterized by difficulty with attention, concentration, and processing speed, independent of lesion size or location. We use magnetoencephalography (MEG) to show that disruption of network dynamics may be responsible. Nine patients with recent minor strokes and eight age-similar controls underwent cognitive screening using the Montreal cognitive assessment (MoCA) and MEG to evaluate differences in cerebral activation patterns. During MEG, subjects participated in a visual picture–word matching task. Task complexity was increased as testing progressed. Cluster-based permutation tests determined differences in activation patterns within the visual cortex, fusiform gyrus, and lateral temporal lobe. At visit 1, MoCA scores were significantly lower for patients than controls (median [interquartile range] = 26.0 [4] versus 29.5 [3], P = 0.005), and patient reaction times were increased. The amplitude of activation was significantly lower after infarct and demonstrated a pattern of temporal dispersion independent of stroke location. Differences were prominent in the fusiform gyrus and lateral temporal lobe. The pattern suggests that distributed network dysfunction may be responsible. Additionally, controls were able to modulate their cerebral activity based on task difficulty. In contrast, stroke patients exhibited the same low-amplitude response to all stimuli. Group differences remained, to a lesser degree, 6 mo later; while MoCA scores and reaction times improved for patients. This study suggests that function is a globally distributed property beyond area-specific functionality and illustrates the need for longer-term follow-up studies to determine whether abnormal activation patterns ultimately resolve or another mechanism underlies continued recovery.

Advances in acute stroke treatment have significantly reduced motor and language deficits, converting highly morbid large hemispheric lesions into smaller infarcts with better overall long-term outcomes (1, 2). Prior work has shown that the majority of individuals presenting for follow-up 4- to 6-wk postinfarct now exhibit what would be classified as “minor symptoms,” (3) with low stroke severity measured by the NIH Stroke Scale (NIHSS) (4) and modified Rankin Scale (mRS) (5) scores. Although these individuals lack a dense hemiparesis or aphasia, over half endorse some degree of cognitive impairment that significantly impacts their recovery. Interestingly, these symptoms are typically found to be independent of stroke size, location, or coexisting depression (6, 7).Poststroke cognitive decline has a substantial presence in the literature (8–13). However, we find that rather than memory impairment or confusion, patients without prior cognitive disability report immediate difficulty with executive function, focus, concentration, and attention after a minor stroke, hereafter referred to as poststroke acute dysexecutive syndrome (PSADES) (3). Dysexecutive syndrome has been previously described in individuals with anatomic lesions (14) as well as disorders, such as schizophrenia (15) and Alzheimer’s disease (14), affecting the frontal lobes. When mild, the syndrome can be hard for others to appreciate, particularly, in previously high-functioning individuals, but poststroke, these deficits are detectable on screening tests, such as the Montreal cognitive assessment (MoCA) (16) and other scales of activities of daily living compared to age-matched controls (3). Despite the fact that following stroke, symptoms typically improve over the first 3–6 mo of recovery, PSADES impedes many successful well-educated individuals from returning to cognitively driven professions given the uncertainty of their prognosis. These decisions affect lifestyle and quality of life, resulting in lasting long-term consequences.The pathophysiology underlying PSADES is poorly understood, as many times the inciting infarct is small and does not involve an area of the brain classically thought to be important for cognitive processing. Cognitive change due to deep white matter lesions (in multiplicity) has been well described (17), but there is no clear unifying physiological explanation regarding how a single small cortical or subcortical lesion may cause significant generalized cortical dysfunction. Some posit a “network” hypothesis suggesting that an individual requires an extensive system of neuronal connectivity, involving numerous cortical and subcortical regions, in order to complete a task (18). We propose that the cognitive dysfunction of PSADES may be the result of a disruption of general network dynamics due to lesions of the subcortical white matter tracts, which would, in turn, interfere with basic network function.This study was designed as a first step in evaluating the role of network dynamics during tasks requiring attention, concentration, speed, and accuracy; all skills difficult for patients poststroke. We used magnetoencephalography (MEG) to determine the differences in cerebral activation patterns in nine individuals with small strokes versus a group of eight age-similar controls by measuring the amplitude and latency of cerebral responses during a visual comprehension task at two time points: ∼1- and 6-mo postinfarct. Our analysis focused on the early visual, M170, and M400 components of the event-related potential from the occipital lobe, fusiform gyrus, and lateral temporal lobe given their importance in visual recognition and language processing (19–22).     

Genome-wide toxicogenomic study of the lanthanides sheds light on the selective toxicity mechanisms associated with critical materials

Lanthanides are a series of critical elements widely used in multiple industries, such as optoelectronics and healthcare. Although initially considered to be of low toxicity, concerns have emerged during the last few decades over their impact on human health. The toxicological profile of these metals, however, has been incompletely characterized, with most studies to date solely focusing on one or two elements within the group. In the current study, we assessed potential toxicity mechanisms in the lanthanide series using a functional toxicogenomics approach in baker’s yeast, which shares many cellular pathways and functions with humans. We screened the homozygous deletion pool of 4,291 Saccharomyces cerevisiae strains with the lanthanides and identified both common and unique functional effects of these metals. Three very different trends were observed within the lanthanide series, where deletions of certain proteins on membranes and organelles had no effect on the cellular response to early lanthanides while inducing yeast sensitivity and resistance to middle and late lanthanides, respectively. Vesicle-mediated transport (primarily endocytosis) was highlighted by both gene ontology and pathway enrichment analyses as one of the main functions disturbed by the majority of the metals. Protein–protein network analysis indicated that yeast response to lanthanides relied on proteins that participate in regulatory paths used for calcium (and other biologically relevant cations), and lanthanide toxicity included disruption of biosynthetic pathways by enzyme inhibition. Last, multiple genes and proteins identified in the network analysis have human orthologs, suggesting that those may also be targeted by lanthanides in humans.

Since their discovery, lanthanides have presented both difficulty and opportunity for researchers. As a series, these elements behave rather similarly: most of them form +3 ions in aqueous solution (1), prefer highly electronegative anionic ligands (2), and form insoluble hydroxide precipitates at neutral pH if not otherwise complexed (3). Although the chemical similarities between these elements made their initial isolation and characterization a significant challenge, they now have unique applications in industry and medicine. Several lanthanides have become critical materials for many clean and sustainable energy technologies that will drive the future of our societies and are used, for example, in the production of batteries, magnets, motors, and other electronic components (4); low-concentration mixtures of lanthanides are used in Chinese agriculture to increase body weight gain among livestock (5, 6); lanthanum carbonate (sold under the commercial name of Fosrenol) is a noncalcium phosphate binder used to control hyperphosphataemia (7); and gadolinium is employed in diagnostic medicine, as an essential component of MRI contrast agents (8, 9).The growing use of lanthanides has increased the potential for human exposure to large concentrations of these metals, requiring more detailed investigations into their toxicological properties. For instance, administration of gadolinium-based contrast agents has been associated with the development of nephrogenic systemic fibrosis in patients with compromised renal function (10–12). Moreover, accumulation of gadolinium in the brains of patients who received repeated doses of gadolinium-based contrast agents has also been reported (13). Despite the current ubiquity of lanthanides, their toxicological profile has been incompletely characterized because until recently they were considered to be of low toxicological concern (14, 15). Previous toxicity studies primarily focused on lanthanum or cerium (and, to a lesser extent, neodymium and gadolinium), with the notion that these metals were representative of the series (14, 16–18). However, to our knowledge, no comprehensive mechanistic assay has been conducted to evaluate metal toxicity across the series, and little is known about what toxicological mechanisms may be shared by the different lanthanides.Saccharomyces cerevisiae is one of the best-characterized model organisms (19, 20), and there are many tools available for analyzing its genomic data (21–23). For example, yeast functional toxicogenomic screening is a powerful tool for investigating cellular mechanisms of cytotoxicity (24, 25). This method makes use of the yeast deletion libraries generated by the Yeast Deletion Project (26), a consortium of researchers across the United States and Canada, to establish relationships between genes and chemical exposures. Researchers used heterozygous and homozygous deletion pools of barcoded yeast strains to derive mechanistic toxicological information about a wide array of chemicals, pharmaceuticals, metals, and biological compounds (27, 28). As eukaryotes, yeast and humans share many cellular pathways and functions, and many components of cell biology identified in S. cerevisiae have homologs in human biology (29–31). Consequently, functional toxicogenomic screening offers unique opportunities to evaluate the mechanisms of cytotoxicity and general biological activity across the lanthanide series in yeast and explore potentially conserved mechanisms in humans.Here, we identify fundamental cellular functions disrupted by lanthanides using functional toxicogenomics in S. cerevisiae. The metals studied had distinct behaviors: early lanthanides showed limited unique functional effects, while middle and late lanthanides had prominent and distinct ones. Although the functional effects of each lanthanide were different and suggested some very efficient element discrimination by endogenous molecules, we observed a few common trends. In particular, vesicle-mediated transport (primarily endocytosis) was perturbed by the majority of the lanthanides tested. Moreover, protein–protein network analysis suggested that lanthanides mimic calcium ions, interacting with calcium-binding proteins and disrupting processes regulated by this cation. Finally, several of the highly interconnected proteins targeted by multiple lanthanides in the network analysis are conserved in humans, suggesting their roles in the origin of the human health issues associated with lanthanide exposure and opening many directions for the determination of mechanisms associated with toxicity.     

Review of the safety and efficacy of risedronate for the treatment of male osteoporosis

Osteoporosis in men is an increasingly recognized problem with associated fracture morbidity and mortality. Treatment is limited, with the bisphosphonates being the mainstay of therapy. Risedronate has demonstrated fracture efficacy in women and efficacy has been recently been investigated in men. In men, risedronate either maintains or increases bone mineral density. In placebo controlled trials it has been shown to be safe and effective in preventing fractures.     

The perplexing complexity of cardiac arrhythmias: Beyond electrical remodeling

Cardiac arrhythmias continue to pose a major medical challenge and significant public health burden. Atrial fibrillation, the most prevalent arrhythmia, affects more than two million Americans annually and is associated with a twofold increase in mortality. In addition, more than 250,000 Americans each year suffer ventricular arrhythmias, often resulting in sudden cardiac death. Despite the high incidence and societal impact of cardiac arrhythmias, presently there are insufficient insights into the molecular mechanisms involved in arrhythmia generation, propagation, and/or maintenance or into the molecular determinants of disease risk, prognosis, and progression. In addition, present therapeutic strategies for arrhythmia abatement often are ineffective or require palliative device therapy after persistent changes in the electrical and conduction characteristics of the heart have occurred, changes that appear to increase the risk for arrhythmia progression. This article reviews our present understanding of the complexity of mechanisms that regulate cardiac membrane excitability and cardiac function and explores the role of derangements in these mechanisms that interact to induce arrhythmogenic substrates. Approaches are recommended for future investigations focused on providing new mechanistic insights and therapeutic interventions.