Or Dgany

Production of Bioactive, Post-Translationally Modified, Heterotrimeric, Human Recombinant Type-I Collagen in Transgenic Tobacco †

Collagens biocompatibility, biodegradability and low immunogenicity render it advantageous for extensive application in pharmaceutical or biotechnological disciplines. However, typical collagen extraction from animal or cadaver sources harbors risks including allergenicity and potential sample contamination with pathogens. In this work, two human genes encoding recombinant heterotrimeric collagen type I (rhCOL1) were successfully coexpressed in tobacco plants with the human prolyl-4-hydroxylase (P4H) and lysyl hydroxylase 3 (LH3) enzymes, responsible for key posttranslational modifications of collagen. Plants coexpressing all five vacuole-targeted proteins generated intact procollagen yields of approximately 2% of the extracted total soluble proteins. Plant-extracted rhCOL1 formed thermally stable triple helical structures and demonstrated biofunctionality similar to human tissue-derived collagen supporting binding and proliferation of adult peripheral blood-derived endothelial progenitor-like cells. Through a simple, safe and scalable method of rhCOL1 production and purification from tobacco plants, this work broadens the potential applications of human recombinant collagen in regenerative medicine.

SP1 protein-based nanostructures and arrays.

Controlled formation of complex nanostructures is one of the main goals of nanoscience and nanotechnology. Stable Protein 1 (SP1) is a boiling-stable ring protein complex, 11 nm in diameter, which self-assembles from 12 identical monomers. SP1 can be utilized to form large ordered arrays; it can be easily modified by genetic engineering to produce various mutants; it is also capable of binding gold nanoparticles (GNPs) and thus forming protein-GNP chains made of alternating SP1s and GNPs. We report the formation and the protocols leading to the formation of those nanostructures and their characterization by transmission electron microscopy, atomic force microscopy, and electrostatic force microscopy. Further control over the GNP interdistances within the protein-GNP chains may lead to the formation of nanowires and structures that may be useful for nanoelectronics.

Crystallization and preliminary X-ray crystallographic analysis of SP1, a novel chaperone-like protein.

SP1 (108 amino acids) is a boiling-stable stress-responsive protein. It has no significant sequence homology to other stress-related proteins or to small heat-shock proteins (sHsps). SP1 activity is ATP-independent, similar to other small heat-shock proteins. Based on these features, it is expected that the structure-function relationship of SP1 will be unique. In this work, the crystallization and preliminary crystallographic data of native SP1 and its selenomethionine derivative are described. Recombinant SP1 and its selenomethionine derivative were expressed in Escherichia coli and used for crystallization experiments. SP1 crystals were grown from 0.1 M HEPES pH 7.5, 20% PEG 3K, 0.2 M NaCl. One to four single crystals appeared in each droplet within a few Days and grew to dimensions of about 0.5 x 0.5 x 0.8 mm after about two weeks. Diffraction studies of these crystals at low temperature indicated that they belong to space group I422, with unit-cell parameters a = 89, b = 89, c = 187 A. Efforts to crystallize the selenomethionine derivative of SP1 are in progress.

Float and Compress : Honeycomb-like Array of a Highly Stable Protein Scaffold

Organizing nano-objects, proteins in particular, on surfaces is one of the primary goals of bio/chemical nanotechnology. A highly stable protein scaffold (6His-SP1) was organized into a hexagonal 2D array by a new, versatile method. The protein was expelled from solution into the air/water interface and compressed in a Langmuir trough into a closely packed monolayer without the use of phospholipids or other surfactants at the interface. The 2D arrays formed at the air/water interface were characterized by transmission electron microscopy (TEM) and atomic force microscopy (AFM).