The Bittersweet Reality: The Cardiovascular Risk of Artificial Sweeteners.

Artificial sweeteners are increasingly popular as alternatives to sugar. Approximately 41% of the American adult population reports regular consumption of low-calorie sweeteners. People are not even aware they are ingesting artificial sweeteners as they are now in chewing gum, toothpaste, various food products, baked goods, and even pharmaceutical products. Some of these sweeteners are sweeter than sugar, some less sweet than sugar, and some are natural sweeteners. With the goal of increasing palatability, many products have multiple additives to create the perfect taste. Despite their widespread use and perceived benefits, there is increasing concern in the academic community about the long-term safety of these artificial sweeteners and their role in increasing the burden of cardiovascular diseases, including coronary heart disease, stroke, and heart failure. There is general agreement about the cardiovascular risk of added sugars to a diet. Public health authorities have recommended limiting added sugar consumption. Replacing sugar with these artificial sweeteners has become increasingly popular, but safety remains a question. While multiple well-designed randomized clinical trials are needed for the conclusion, review of the current literature gives us pause about the cardiovascular risk and long-term safety of these additives.

Central Spindle Self-Organization and Cytokinesis in Artificially Activated Sea Urchin Eggs.

The ability of microtubules of the mitotic apparatus to control the positioning and initiation of the cleavage furrow during cytokinesis was first established from studies on early echinoderm embryos. However, the identity of the microtubule population that imparts cytokinetic signaling is unclear. The two main--and not necessarily mutually exclusive--candidates are the central spindle and the astral rays. In the present study, we examined cytokinesis in ammonia-activated sea urchin eggs, which lack paternally derived centrosomes and undergo mitosis mediated by unusual anastral, bipolar mini-spindles. Live cell imaging and immunolabeling for microtubules and the centralspindlin constituent and kinesin-related protein, MKLP1, demonstrated that furrowing in ammonia-activated eggs was associated with aligned arrays of centralspindlin-linked, opposed bundles of antiparallel microtubules. These autonomous, zipper-like arrays were not associated with a mitotic apparatus, but did possess characteristics similar to the central spindle region of control, fertilized embryos. Our results highlight the self-organizing nature of the central spindle region and its ability to induce cytokinesis-like furrowing, even in the absence of a complete mitotic apparatus.

Arp2/3 complex inhibition radically alters lamellipodial actin architecture, suspended cell shape, and the cell spreading process.

Recent studies have investigated the dendritic actin cytoskeleton of the cell edge's lamellipodial (LP) region by experimentally decreasing the activity of the actin filament nucleator and branch former, the Arp2/3 complex. Here we extend these studies via pharmacological inhibition of the Arp2/3 complex in sea urchin coelomocytes, cells that possess an unusually broad LP region and display correspondingly exaggerated centripetal flow. Using light and electron microscopy, we demonstrate that Arp2/3 complex inhibition via the drug CK666 dramatically altered LP actin architecture, slowed centripetal flow, drove a lamellipodial-to-filopodial shape change in suspended cells, and induced a novel actin structural organization during cell spreading. A general feature of the CK666 phenotype in coelomocytes was transverse actin arcs, and arc generation was arrested by a formin inhibitor. We also demonstrate that CK666 treatment produces actin arcs in other cells with broad LP regions, namely fish keratocytes and Drosophila S2 cells. We hypothesize that the actin arcs made visible by Arp2/3 complex inhibition in coelomocytes may represent an exaggerated manifestation of the elongate mother filaments that could possibly serve as the scaffold for the production of the dendritic actin network.