Venous ulcer: what is new?

The pathophysiology of venous dermal abnormality in chronic venous ulcers is reflective of a complex interplay that involves sustained venous hypertension, inflammation, changes in the microcirculation, cytokine and matrix metalloproteinase activation, and altered cellular function. Red blood cells and macromolecules extravasate into the interstitium and activate endothelial cells. Endothelial expression of specific adhesion molecules recruits leukocytes and causes diapedesis of these cells into the dermal microvasculature, promoting an inflammatory response with activation of cytokines and proteinases. Altered cell function enhances a state of vulnerability in the surrounding tissues, initiating specific changes associated with venous disease. Ultimately, the persistent inflammatory-proteinase activity leads to advanced chronic venous insufficiency and ulcer formation. The mainstay of therapy in venous ulcer abnormality is correction of the underlying venous hypertension through compression therapy and/or surgery. Understanding the science involved in the pathophysiology of venous ulcer formation has led to the development of adjunctive treatment directed at the dysregulated molecular pathways. Randomized clinical trials are critical for determining the most effective evidence-based treatments for venous ulcer, and this review discusses important trials that have had a significant impact on venous ulcer healing. In addition, the authors have included subsections referred to as "Translational Implications for Therapy" in the basic science sections of the review to help bridge the basic science knowledge with clinical applications that may help to modulate the molecular abnormalities in the pathophysiologic cascade leading to venous ulcers.     

Statin therapy and stroke prevention: what was known, what is new and what is next?

PURPOSE OF REVIEW: Randomized trials have shown that statins may reduce the risk of primary stroke. There is no evidence however that statins can reduce recurrent stroke incidence. RECENT FINDINGS: In the SPARCL trial, patients with a recent stroke or transient ischemic attack randomized to atorvastatin 80 mg/day had a significant 16% relative risk reduction of stroke, and a 35% reduction in major coronary events compared with placebo. This was obtained despite 25% of the placebo arm patients receiving a commercially-available statin outside of the trial. Post-hoc analysis used blinded LDL-cholesterol measurements as a marker of adherence to lipid-lowering therapy. Compared with the group with no change or an increase in LDL-cholesterol (the group adherent to placebo or not taking a statin), the group with over 50% reduction in LDL-cholesterol had a significant 31% reduction in stroke. The next step is to define whether achieving LDL-cholesterol below 70 mg/dl is better than a standard dose of statin (LDL around 100-110 mg/dl) in the secondary prevention of stroke. SUMMARY: Statins are effective in reducing both first-ever and recurrent stroke, and this effect seems driven by the extent of LDL-cholesterol lowering.     

Phosphatidylserine receptors: what is the new RAGE?

The identification of RAGE as a phophatidylserine receptor—in this issue of EMBO reports by He et al—adds to the range of molecules that can sense this ‘eat-me'' signal, and suggests new potential therapeutic opportunities.EMBO Rep (2011) advance online publication. doi:10.1038/embor.2011.28The recognition of apoptotic cells by phagocytes is a complex, yet highly orchestrated event. Many receptors have been identified that recognize phosphatidylserine (PS; Fig 1)—which is exposed on early apoptotic cells—leading to downstream signalling and apoptotic cell engulfment. In a paper published this month in EMBO reports, the receptor for advanced glycation end-products (RAGE) is described as a new PS receptor on alveolar macrophages that participates in the clearance of apoptotic cells (He et al, 2011).…[RAGE] is described as a new phosphatidylserine receptor on alveolar macrophages that participates in the clearance of apoptotic cellsOpen in a separate windowFigure 1Phosphatidylserine-dependent apoptotic cell recognition.Schematic of the known PS receptors and downstream signalling to Rac. Dashed lines indicate unknown signalling mechanisms. PS, phosphatidylserine; RAGE, receptor for advanced glycation end-products; sRAGE, soluble RAGE.More than 200 billion cells undergo apoptosis every day in a human body, yet few apoptotic cells are detected in healthy tissue (Ravichandran, 2010). Apoptotic cells are generated during development, as part of normal homeostatic turnover and in disease states. The efficient clearance of apoptotic cells is crucial to prevent them from becoming secondarily necrotic, thereby limiting the immune response to apoptotic cell-derived self-antigens (Green et al, 2009). Disruptions to the clearance of apoptotic cells are linked to several diseases including atherosclerosis, chronic inflammation and autoimmunity (Elliott & Ravichandran, 2010).More than 200 billion cells undergo apoptosis every day in a human body, yet few apoptotic cells are detected in healthy tissueApoptotic cell engulfment can be divided into several steps. The first is the release of ‘find-me'' signals—such as triphosphate nucleotides (ATP and UTP), sphingosine-1-phosphate (S1P), lysophosphatidylcholine (LPC) and the chemokine CX₃CL1—by apoptotic cells (Ravichandran, 2010). Then, phagocytes sense the find-me signals and migrate toward the apoptotic cell. When they are in close proximity, recognition is mediated by the interaction between engulfment receptors on phagocytes and ligands, known as ‘eat-me'' signals, that are expressed on the dying cells (Ravichandran, 2010). The best-studied eat-me signal is PS, which is flipped from the inner leaflet to the outer leaflet of the plasma membrane during early apoptosis. Many receptors have been linked to the recognition of the exposed PS on apoptotic cells, and they are discussed below. The recognition of an apoptotic cell results in a downstream signalling cascade that leads to cytoskeletal rearrangement of the phagocytic membrane and subsequent engulfment of the apoptotic cell. Once the corpse is internalized, the phagocyte must process and digest the cellular contents.The exposure of PS on the outer leaflet of the membrane is the most-characteristic marker of an apoptotic cell. Phagocytes can recognize PS directly through receptors such as Bai1, TIM-4 and stabilin 2, or through soluble bridging molecules that bind to both PS and specific phagocyte receptors. For example, bridging molecules MFG-E8 and Gas6 interact with α_Vβ_3/5 and MER on the phagocytic membrane, respectively. Other eat-me signals and the molecules that bind to them have been characterized: thrombospondin is recognized by the vitronectin receptor, calreticulin by LRP1, oxidized LDL by scavenger receptors, ICAM3 might bind to CD14 and altered sugars bind to lectins (Lauber et al, 2004). Not all receptors need to be engaged for engulfment to occur, and different cell types have different receptor-expression levels.In a paper published this month in EMBO reports, the Yamamoto team identify RAGE as a new type of PS receptor on macrophages (He et al, 2011). There are two functional forms of RAGE, an abundant full-length transmembrane form that can initiate signalling through its intracellular tail, and a soluble isoform (sRAGE) that acts as a decoy receptor. RAGE is characteristically regarded as a pro-inflammatory receptor and has a variety of ligands, including advanced glycation end-products (AGEs) and many other damage-associated molecular patterns (DAMPs; Sims et al, 2010). One ligand in particular—high-mobility group protein B1 (HMGB1)—is released by cells undergoing necrosis and has been shown to bind to RAGE and induce inflammation (Sims et al, 2010). Therefore, RAGE might function during pro-inflammatory conditions and—as proposed by He and colleagues—during the anti-inflammatory process of apoptotic cell clearance. RAGE is mainly expressed in the lungs, but levels of it quickly increase at sites of inflammation, mostly on inflammatory and epithelial cells. Given the multitude of RAGE ligands and its inducible expression levels, RAGE is implicated in a variety of inflammation-related pathological states such as neurological and pulmonary disorders, vascular disease, cancer and diabetes (Sims et al, 2010).He and colleagues suggest that RAGE is a PS receptor during apoptotic cell engulfment in alveolar macrophages (He et al, 2011). Furthermore, sRAGE—which can bind to PS and apoptotic thymocytes—acts as a decoy and inhibits RAGE recognition of PS. By using PS liposomes as an artificial apoptotic target, the authors find RAGE in areas of the membrane in which a pseudopod forms to engulf a PS liposome. Additionally, sRAGE can compete with transmembrane RAGE to block the recognition of PS by the phagocyte and subsequently decrease the engulfment of apoptotic cells. Under homeostatic conditions, alveolar macrophages isolated from RAGE-deficient mice have defects in phagocytosis of apoptotic thymocytes. In a model of lung injury induced by lipopolysaccharide administration, RAGE-deficient mice accumulate neutrophils in the alveolar space and RAGE-deficient macrophages have defects in neutrophil engulfment. Previous works have implicated RAGE expression and/or upregulation in inflammatory conditions. In fact, genetic deletion of RAGE in mice can result in attenuated atherosclerosis, resistance to septic shock and reduced diabetic kidney disease (Ramasamy et al, 2010). Apoptotic cell clearance is generally an immunologically silent process and, therefore, if RAGE significantly contributes to engulfment, RAGE-deficient mice would be expected to have defects in cell clearance, leading to enhanced inflammation and disease. However, this does not seem to be the case. Thus, future studies should examine cell-type specific deletions of RAGE to clarify its apparently contradictory role in cell clearance and inflammation in these diseases.Given that several modes of PS recognition have been identified (Ravichandran, 2010), there must be some redundancy. The way in which RAGE contributes to this scenario remains to be investigated. Analysis of the expression levels of each PS receptor on different cell types will also help to define their relative importance in individual cells. As RAGE is highly expressed in the lung, it would be interesting to analyse its contribution to apoptotic cell engulfment in this tissue, in comparison with the other PS receptors. Furthermore, RAGE is induced by inflammation, suggesting that it is probably important during disease states to facilitate engulfment and reduce inflammation in the microenvironment.Another interesting question that remains is how RAGE signals to the phagocyte for engulfment. RAGE signalling results in pro-inflammatory cytokine production through activation of NF-κB (Yan et al, 1994), which seems to be different from the production of anti-inflammatory cytokines—such as IL-10 and TGFβ—by phagocytes during cell engulfment. However, as several RAGE ligands exist, the way in which they bind to RAGE could result in differential signalling. RAGE has also been shown to interact with mouse Dia1, leading to downstream activation of Rac1 and Cdc42, and cell migration (Hudson et al, 2008). Now, He and colleagues suggest that RAGE signals to Rac1 through Dia1 in the context of apoptotic cell clearance, as RAGE-deficient macrophages have decreased Rac1 activity in response to PS-liposome engulfment. Two evolutionarily conserved Rac-dependent pathways have been identified to mediate corpse internalization. Engagement of some engulfment receptors such as Bai1, results in Rac activation through the ELMO–Dock180–CrkII complex. ELMO and Dock180 mediate the exchange of GDP to GTP on Rac, whereas CrkII has been proposed to function as an adaptor protein. Another pathway involves signalling from the engulfment receptor LRP1 or stabilin 2, leading to Rac activation through the engulfment adaptor protein (GULP). Additional work is necessary to determine whether RAGE–mDia1 signalling constitutes a third intracellular signalling pathway for cell engulfment.Another interesting question that remains is how RAGE signals to the phagocyte for engulfmentThe study from the Yamamoto team identifies RAGE as a new PS-recognition molecule implicated in apoptotic cell-clearance in the lung. As each new receptor is identified, we are reminded of the redundancy and cell-type-specific expression of PS receptors. Defects in apoptotic cell-clearance lead to a variety of inflammatory diseases, including cardiovascular and autoimmune diseases. This study could also open an interesting therapeutic avenue; if sRAGE blocks the recognition of PS by RAGE and other PS receptors, it might be beneficial as a therapy by enhancing cell clearance and decreasing the severity of cell-clearance-associated diseases.     

Plasmodium pre-erythrocytic stages: what’s new?

The pre-erythrocytic (PE) phase of malaria infection, which extends from injection of sporozoites into the skin to the release of the first generation of merozoites, has traditionally been the 'black box' of the Plasmodium life cycle. However, since the advent of parasite transfection technology 13 years ago, our understanding of the PE phase in cellular and molecular terms has dramatically improved. Here, we review and comment on the major developments in the field in the past five years. Progress has been made in many diverse areas, including identifying and characterizing new proteins of interest, imaging parasites in vivo, understanding better the cell biology of hepatocyte infection and developing new vaccines against PE stages of the parasite.     

Endogenous retroviruses: Still active after all these years?

Embedded in the genomes of all vertebrates are the proviral remnants of previous retroviral infections. Although the overwhelming majority has suffered inactivating mutations, current research suggests that members of one family of human retroelements may still be capable of movement.     

Thirty years after Brambell: whither animal welfare science?

It has been just over 30 years since the Brambell Committee issued its clarion call for research on the welfare of animals used in agriculture. What progress has farm animal welfare science made in those 30 years, and what challenges will it face in the next 30? In this article, I discuss the ways in which the Brambell report, with its emphasis on behavioral needs and suffering, both propelled and constrained the development of animal welfare science. The role that economic factors play and the ways in which they have imposed other kinds of constraints on scientists working with farm animals are also mentioned. Despite these constraints, animal welfare science has contributed to a number of significant improvements in the welfare of farm animals. There is, however, a growing sense that animal welfare science has reached an impasse and that ethical and scientific questions about animal welfare have become hopelessly entangled. In this context, I address what I view to be the principal challenge facing farm animal welfare science, namely to move the issue of beyond suffering to an evaluation of broader quality-of-life questions and their application to improvements in welfare.     

Age and growth of the round goby Neogobius melanostomus in the Gulf of Gdańsk several years after invasion. Is the Baltic Sea a new Promised Land?

The ages of 8 to 23·5 cm total length (L(T)) round goby Neogobius melanostomus collected monthly during 2006 and 2007 in the Gulf of Gdańsk (Baltic Sea) ranged from 2 to 6 years, with age class 4+ years dominant. Males were larger at age than females. The fastest growth occurred in the first 2 years of life in both sexes. Females were heavier at a given L(T) than males, but only for fish > c. 15 cm. A strong relationship between N. melanostomus otolith size and fish size was found, with no difference between males and females, and a significant relationship between fish growth rate and otolith growth rate, which enabled backcalculation of growth rates. Marginal increment width analysis confirmed the periodicity of annual ring formation in otoliths and showed that the most intense opaque zone formation occurs in July to August, while hyaline zone formation starts as early as September to October. It was concluded that the N. melanostomus that have colonized the southern Baltic Sea exhibit the largest size and longest life span ever recorded for this species.     

Selenium intake and cardiovascular risk: what is new?

PURPOSE OF REVIEW: Selenium is an essential element with a narrow safety margin. Adequate selenium intake is needed to maximize the activity of glutathione peroxidases and other selenoproteins. This review discusses recent experimental and epidemiologic contributions on the role of selenium for the prevention of atherosclerotic cardiovascular disease. RECENT FINDINGS: Few randomized trials have evaluated the efficacy of selenium supplementation on cardiovascular endpoints. Most trials, conducted in selenium-replete populations, found no evidence of cardiovascular protection. A meta-analysis of 13 prospective cohort studies found a moderate inverse relationship between plasma/serum selenium and coronary heart disease. The interpretation of these data is complicated, however, by potential residual confounding and publication bias. In contrast, recent data from trials of selenium-containing supplements and from epidemiologic studies suggest that chronically increased selenium intake in selenium-replete populations can induce diabetes and maybe also hypercholesterolemia. SUMMARY: Current evidence is insufficient to support a protective role for selenium in cardiovascular prevention. Large high-quality randomized controlled trials and observational studies are needed across populations with different levels of selenium intake. Furthermore, subjects living in regions with high selenium intake should be aware that selenium supplements may increase their risk of diabetes and hypercholesterolemia.     

Vegetation change in Southeast Greenland? Tasiilaq revisited after 40 years

Questions: Are there changes in species composition of the oceanic, Low‐Arctic tundra vegetation after 40 years? Can possible changes be attributed to climate change? Location: Ammassalik Island near Tasiilaq, Southeast Greenland. Methods: Species composition and cover of 11 key vegetation types were recorded in 110 vegetation survey plots in 1968–1969 and in 11 permanent plots in 1981. Recording was repeated in 2007. Temporal changes in species composition and cover between the surveys were tested using permutation tests linked with constrained ordinations for vegetation types, and Mann–Whitney tests for individual species. Changes in vegetation were related to climate change. Results: Although climate became warmer over the studied period, most of the vegetation types showed minor changes. The changes were most conspicuous in mire and snowbed vegetation, such as the Carex rariflora mire and Hylocomium splendens snowbed. In the C. rariflora mire, species number and cover of vascular plants and cover of bryophytes increased, whereas in the H. splendens snowbed species numbers of vascular plants, bryophytes, and also lichens increased. Lichen richness increased in the Carex bigelowii snowbed and cover of bryophytes in the Salix herbacea snowbed. No such changes occurred in the Alchemilla glomerulans meadow, Alchemilla alpina snowbed and Phyllodoce coerulea heath. There was no change of species composition within the Salix glauca scrub, A. alpina snowbed, lichen grassland and the Empetrum nigrum and Phyllodoce coerulea heaths. Most changes resulted from increasing frequency or cover of some species; there were very few decreasing species. Most of the increasing species indicate drier substrate conditions. Conclusions: Only minor changes in species composition and cover were detected in the vegetation types studied. These changes were probably caused by milder winters and warmer summers during the years before the 2007 sampling. Climate warming may have reduced the duration of snow cover and soil moisture, particularly in snowbed and mire habitats, where species composition change was most pronounced. However, its magnitude was insufficient to cause a major change in species composition. Thus, on the level of plant community types, tundra vegetation near Tasiilaq was rather stable over the last 40 years.