Matrix remodeling in vascular calcification associated with chronic kidney disease.

Vascular calcification is a major contributor to cardiovascular disease, a leading cause of death in patients with chronic kidney disease. Mechanistic studies highlight the importance of dysregulated mineral metabolism, vascular osteochondrogenic processes, apoptosis, and deficiencies in calcification inhibitors as potential mediators of calcification in renal disease. However, the contribution of the extracellular matrix in vascular calcification associated with chronic kidney disease is less understood. Here we examine evidence that suggests important roles for elastin and elastin-degrading enzymes as potential key regulators of calcification. Additional studies aimed at further understanding their role are critical for the design of therapeutic interventions.

Phosphate feeding induces arterial medial calcification in uremic mice: role of serum phosphorus, fibroblast growth factor-23, and osteopontin.

Arterial medial calcification is a major complication in patients with chronic kidney disease and is a strong predictor of cardiovascular and all-cause mortality. We sought to determine the role of dietary phosphorus and the severity of uremia on vascular calcification in calcification-prone DBA/2 mice. Severe and moderate uremia was induced by renal ablation of varying magnitudes. Extensive arterial-medial calcification developed only when the uremic mice were placed on a high-phosphate diet. Arterial calcification in the severely uremic mice fed a high-phosphate diet was significantly associated with hyperphosphatemia. Moderately uremic mice on this diet were not hyperphosphatemic but had a significant rise in their serum levels of fibroblast growth factor 23 (FGF-23) and osteopontin that significantly correlated with arterial medial calcification. Although there was widespread arterial medial calcification, there was no histological evidence of atherosclerosis. At early stages of calcification, the osteochondrogenic markers Runx2 and osteopontin were upregulated, but the smooth muscle cell marker SM22alpha decreased in medial cells, as did the number of smooth muscle cells in extensively calcified regions. These findings suggest that phosphate loading and the severity of uremia play critical roles in controlling arterial medial calcification in mice. Further, FGF-23 and osteopontin may be markers and/or inducers of this process.

PEGylated phospholipid nanomicelles interact with beta-amyloid((1-42)) and mitigate its beta-sheet formation, aggregation and neurotoxicity in vitro.

beta-Amyloid (Abeta) is a hydrophobic peptide that drives the pathogenesis of Alzheimer's disease (AD) due to its aberrant aggregation. Inhibition of Abeta aggregation process is one of the most promising strategies for therapeutic intervention in AD. Here, we demonstrate that sterically stabilized (PEGylated) phospholipid nanomicelles (SSM) are effective in mitigating Abeta-42 aggregation using several deterministic techniques such as (1) Turbidimetry (2) Congo red binding (3) Thioflavine-T binding (4) Laser light scattering and (5) Electron Microscopy. alpha-Helicity of Abeta-42 is significantly augmented in the presence of SSM as demonstrated by circular dichroism (p<0.05). Cytotoxicity studies, employing human neuroblastoma SHSY-5Y cells, established that PEGylated phospholipid associated peptide demonstrated significantly lower neurotoxicity compared to lipid untreated Abeta-42 (p<0.05). Collectively, our results establish that PEGylated phospholipids abrogate transformation of Abeta-42 to amyloidogenic beta-sheeted form and impart neuroprotection in vitro. This study provides a foundation for designing nanoconstructs of PEGylated phospholipid nanomicelles in conjunction with a therapeutic agent for multitargeting the different pathophysiologies associated with AD.