Enhancing osteoblast differentiation through small molecule-incorporated engineered nanofibrous scaffold.

OBJECTIVE: This study aimed to investigate the effect of small molecules incorporated into the engineered nanofibrous scaffold to enhance the osteoblast differentiation MATERIALS AND METHODS: Poly-ε-caprolactone (PCL) nanofiber matrices with lithium chloride (LiCl) were fabricated using the electrospinning technique. Scaffolds were characterized using scanning electron microscopy (SEM) and energy-dispersive X-ray (EDX). Scaffolds were seeded with MC3T3-E1 cells and assessed using Western blots (ß-catenin), alamarBlue assay (proliferation), qPCR (osteoblast differentiation), and mineralization (Alizarin Red staining). RESULTS: We observed LiCl nanofiber scaffolds induced concentration-dependent cell proliferation that correlated with an increased ß-catenin expression indicating sustained Wnt signaling. Next, we examined osteoblast differentiation markers such as osteocalcin (OCN) and Runt-related transcription factor 2 (Runx2) and noted increased expression in LiCl nanofiber scaffolds. We also noted increased bone morphogenetic protein (BMP-2, 4, and 7) expressions suggesting activated Wnt can promote cures to further osteogenic differentiation. Finally, Alizarin Red staining demonstrated increased mineral deposition in LiCl-incorporated nanofiber scaffolds. CONCLUSIONS: Together, these results indicated that LiCl-incorporated nanofiber scaffolds enhance osteoblast differentiation. CLINICAL RELEVANCE: Small molecule-incorporated nanofibrous scaffolds are an innovative clinical tool for bone tissue engineering.

Highly selective recovery of phosphopeptides using trypsin-assisted digestion of precipitated lanthanide-phosphoprotein complexes.

The basic idea of this study was to recover phosphopeptides after trypsin-assisted digestion of precipitated phosphoproteins using trivalent lanthanide ions. In the first step, phosphoproteins were extracted from the protein solution by precipitation with La(3+) and Ce(3+) ions, forming stable pellets. Additionally, the precipitated lanthanide-phosphoprotein complexes were suspended and directly digested on-pellet using trypsin. Non-phosphorylated peptides were released into the supernatants by enzymatic cleavage and phosphopeptides remained bound on the precipitated pellet. Further washing steps improved the removal of non-phosphorylated peptides. For the recovery of phosphopeptides the precipitated pellets were dissolved in 3.7% hydrochloric acid. The performance of this method was evaluated by several experiments using MALDI-TOF MS measurements and delivered the highest selectivity for phosphopeptides. This can be explained by the overwhelming preference of lanthanides for binding to oxygen-containing anions such as phosphates. The developed enrichment method was evaluated with several types of biological samples, including fresh milk and egg white. The uniqueness and the main advantages of the presented approach are the enrichment on the protein-level and the recovery of phosphopeptides on the peptide-level. This allows much easier handling, as the number of molecules on the peptide level is unavoidably higher, by complicating every enrichment strategy.

A new type of metal chelate affinity chromatography using trivalent lanthanide ions for phosphopeptide enrichment.

In this study, a new type of immobilized metal-ion affinity chromatography (IMAC) resin for the isolation of phosphopeptides was synthesized which is based on the specific interaction between phosphate groups and chelated lanthanide metal ions. In this regard trivalent lanthanum, holmium and erbium ions were chelated to a highly porous phosphonate polymer which was prepared by radical polymerization of vinylphosphonic acid (VPA) and divinylbenzene (DVB). The developed method was evaluated with peptide mixtures from digested standard proteins (α-casein, ß-casein and ovalbumin) as well as with bovine milk, egg white and a spiked HeLa cell lysate. Compared to the commonly used TiO2 approach, the presented method showed higher selectivity for phosphorylated peptides. This can be explained by the strong preference of trivalent lanthanide ions for phosphates with which they form very tight ionic bonds. Mono- and multiply phosphorylated peptides could be enriched and released in a single basic elution step, while non-phosphorylated peptides remained on the resin. Ab initio quantum mechanical energy minimizations of model complexes for polymer-ion-ligand interactions provided geometries, binding energies and charges which are discussed in conjunction with the observed experimental properties, leading to the most satisfying agreement. The presented lanthanide-IMAC resins represent promising affinity materials for the selective isolation of phosphopeptides from biological samples.