Translating biomaterial properties to intracellular signaling.

Bioactive materials present important micro-environmental cues that induce specific intracellular signaling responses which ultimately determine cell behavior. For example, vascular endothelial cells on a normal vessel wall resist inflammation and thrombosis, but the same cells seeded on an artificial vascular graft or stent do not. What makes these cells behave so differently when they are adhered to different materials? Intracellular signaling from integrins and other cell-surface receptors is an important part of the answer, but these signaling responses constitute a highly-branched, interconnected network of molecules. In order to perform rational design of biomaterials, one must understand how altering the properties of the material (micro-environment) causes changes in cell behavior, and this in turn requires understanding the complex signaling response. Systems biology and mathematical modeling aid analysis of the connectivity of this network. This review summarizes applicable systems biology and mathematical modeling techniques including ordinary differential equations-based models, principal component analysis, and Bayesian networks. Next covered is biomaterials research which studies the intracellular signaling responses generated by variation of biomaterial properties. Finally, the review details ways in which modeling has been or could be applied to better understand the link between biomaterial properties and intracellular signaling.

Sialylated endogenous glycoconjugates in plant cells.

Bioengineered plants are emerging as promising systems for the production of therapeutically valuable proteins. It has been commonly accepted that plants do not perform mammalian-like post-translational modifications, particularly sialylation of glycoconjugates, and no evidence has previously been reported to suggest that they have such capabilities. Here we report the presence of sialylated glycoconjugates in suspension-cultured cells of Arabidopsis thaliana and suggest that a genetic and enzymatic basis for sialylation exists in plants.