Smoking is associated with lower amounts of arterial type I collagen and decorin.

BACKGROUND: Smoking affects the arterial wall and increases the risk of cardiovascular disease. It also affects the extracellular matrix in skin, causing impaired wound healing. However, little is known about putative molecular changes in the arterial wall. Our aim was to investigate the possible correlation between extracellular matrix content in arterial tissue and cigarette smoking. METHODS: We studied the non-atherosclerotic arterial wall of the internal mammary artery from coronary artery by-pass surgery in 13 never-smokers and 11 active smokers. Using histomorphometric methods, the area fraction of collagen stainable material was determined. In addition, proteome analysis of matrix molecules and other proteins was performed. RESULTS: The area fraction of collagen stainable material in smokers vs. never-smokers was 29.1% ± 3.8% vs. 43.3% ± 3.6% (mean ± SEM, p = 0.012) in tunica intima, 39.7% ± 5.5% vs. 56.8% ± 5.6% (mean ± SEM, p = 0.042) in tunica media, and 50.4% ± 3.9% vs. 61.0% ± 3.2% (mean ± SEM, p = 0.046) in tunica adventitia. We discovered significantly lower relative levels of collagen α1(I) (0.68 ± 0.048 vs. 1.02 ± 0.112, mean ± SEM, p = 0.013), collagen α2(I) (0.81 ± 0.046 vs. 1.14 ± 0.118, mean ± SEM, p = 0.038) and decorin (0.64 ± 0.04 vs. 0.98 ± 0.11, mean ± SEM, p = 0.009) in smokers. CONCLUSIONS: Arterial tissue from active smokers contains decreased amounts of collagen stainable material, as well as type 1 collagen and decorin. These findings may explain some effects of smoking on the development of cardiovascular disease including compromised remodelling and increased risk of aneurysms.

Proteomic Analysis of Anti-Cancerous Scopularide Production by a Marine Microascus brevicaulis Strain and Its UV Mutant.

The marine fungus Microascus brevicaulis strain LF580 is a non-model secondary metabolite producer with high yields of the two secondary metabolites scopularides A and B, which exhibit distinct activities against tumour cell lines. A mutant strain was obtained using UV mutagenesis, showing faster growth and differences in pellet formation besides higher production levels. Here, we show the first proteome study of a marine fungus. Comparative proteomics were applied to gain deeper understanding of the regulation of production and of the physiology of the wild type strain and its mutant. For this purpose, an optimised protein extraction protocol was established. In total, 4759 proteins were identified. The central metabolic pathway of strain LF580 was mapped using the KEGG pathway analysis and GO annotation. Employing iTRAQ labelling, 318 proteins were shown to be significantly regulated in the mutant strain: 189 were down- and 129 upregulated. Proteomics are a powerful tool for the understanding of regulatory aspects: The differences on proteome level could be attributed to limited nutrient availability in the wild type strain due to a strong pellet formation. This information can be applied for optimisation on strain and process level. The linkage between nutrient limitation and pellet formation in the non-model fungus M. brevicaulis is in consensus with the knowledge on model organisms like Aspergillus niger and Penicillium chrysogenum.

A site-specific phosphorylation of the focal adhesion kinase controls the formation of spheroid cell clusters.

Human dental follicle cells (DFCs) are ectomesenchymal multipotent stem cells that form spheroid cell clusters (SCCs) under serum free medium cell culture conditions (SFM). Until today, molecular mechanisms for the formation of SCCs are unknown. In this study a quantitative phosphoproteomics approach revealed regulated phosphorylated proteins in SCCs, which were derived from DFCs after 24 and 48 h in SFM. These regulated proteins were categorized using the Kyoto encyclopedia of genes and genomes program. Here, cellular processes and signaling pathway were identified such as the focal adhesion kinase (FAK) signaling pathway. In addition to the phosphoproteomics approach we showed that a specific phosphorylation of FAK (Y397) was required for the formation of SCCs. In conclusion, this study disclosed the phosphoproteome of SCCs for the first time and showed that the FAK signaling pathway is required for the formation of SCCs.