Peloruside A, an antimitotic agent, specifically decreases tumor necrosis factor-alpha production by lipopolysaccharide-stimulated murine macrophages

Peloruside A (peloruside) is a naturally occurring compound isolated from a New Zealand marine sponge that, like the anticancer drug paclitaxel, stabilizes microtubules and inhibits mitosis. Paclitaxel is known to induce a proinflammatory response in murine macrophages; whereas, peloruside has never been tested for its immunomodulatory effects in these cells. Although the antimitotic effects of the two drugs appear to be similar, we found that peloruside, unlike paclitaxel, does not induce murine macrophages to produce the proinflammatory mediators interleukin-12p40 (IL-12p40), tumor necrosis factor-alpha (TNF-alpha), and nitric oxide. The 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) reduction assay confirmed that the absence of cytokine production was not caused by cytotoxicity in these nondividing cells. Additionally, there was no effect on unstimulated splenocytes; whereas, both compounds inhibited proliferation after concanalavin A (Con A) stimulation. Finally, there was a significant decrease in TNF-alpha and nitric oxide but not IL-12p40 when macrophages were cultured with lipopolysaccharide (LPS) and either paclitaxel or peloruside. These results suggest that peloruside may prove to be an effective anti-inflammatory treatment, since it does not induce the production of proinflammatory mediators yet can downregulate TNF-alpha and nitric oxide production by LPS-stimulated macrophages, as well as inhibit lymphocyte proliferation.     

Long-term aquatic biomonitoring in a Southern Brazil urban center: the Guaíba Lake fish community structure through the years

Environmental Biology of Fishes - The ichthyofauna of a large lake located in one of the biggest urban centers in Southern South America was studied for 15 years. Variations in...     

Functional Effect of Pim1 Depends upon Intracellular Localization in Human Cardiac Progenitor Cells

Human cardiac progenitor cells (hCPC) improve heart function after autologous transfer in heart failure patients. Regenerative potential of hCPCs is severely limited with age, requiring genetic modification to enhance therapeutic potential. A legacy of work from our laboratory with Pim1 kinase reveals effects on proliferation, survival, metabolism, and rejuvenation of hCPCs in vitro and in vivo. We demonstrate that subcellular targeting of Pim1 bolsters the distinct cardioprotective effects of this kinase in hCPCs to increase proliferation and survival, and antagonize cellular senescence. Adult hCPCs isolated from patients undergoing left ventricular assist device implantation were engineered to overexpress Pim1 throughout the cell (PimWT) or targeted to either mitochondrial (Mito-Pim1) or nuclear (Nuc-Pim1) compartments. Nuc-Pim1 enhances stem cell youthfulness associated with decreased senescence-associated β-galactosidase activity, preserved telomere length, reduced expression of p16 and p53, and up-regulation of nucleostemin relative to PimWT hCPCs. Alternately, Mito-Pim1 enhances survival by increasing expression of Bcl-2 and Bcl-X_L and decreasing cell death after H₂O₂ treatment, thereby preserving mitochondrial integrity superior to PimWT. Mito-Pim1 increases the proliferation rate by up-regulation of cell cycle modulators Cyclin D, CDK4, and phospho-Rb. Optimal stem cell traits such as proliferation, survival, and increased youthful properties of aged hCPCs are enhanced after targeted Pim1 localization to mitochondrial or nuclear compartments. Targeted Pim1 overexpression in hCPCs allows for selection of the desired phenotypic properties to overcome patient variability and improve specific stem cell characteristics.     

Whole-animal imaging, gene function, and the Zebrafish Phenome Project

Imaging can potentially make a major contribution to the Zebrafish Phenome Project, which will probe the functions of vertebrate genes through the generation and phenotyping of mutants. Imaging of whole animals at different developmental stages through adulthood will be used to infer biological function. Cell resolutions will be required to identify cellular mechanism and to detect a full range of organ effects. Light-based imaging of live zebrafish embryos is practical only up to ～2 days of development, owing to increasing pigmentation and diminishing tissue lucency with age. The small size of the zebrafish makes possible whole-animal imaging at cell resolutions by histology and micron-scale tomography (microCT). The histological study of larvae is facilitated by the use of arrays, and histology's standard use in the study of human disease enhances its translational value. Synchrotron microCT with X-rays of moderate energy (10-25 keV) is unimpeded by pigmentation or the tissue thicknesses encountered in zebrafish of larval stages and beyond, and is well-suited to detecting phenotypes that may require 3D modeling. The throughput required for this project will require robotic sample preparation and loading, increases in the dimensions and sensitivity of scintillator and CCD chips, increases in computer power, and the development of new approaches to image processing, segmentation, and quantification.