Skin concentrations of thromboxane synthetase inhibitor after topical application with bioelastic membrane.

Elevated thromboxane levels are associated with a number of disease states, including dermal pressure ulcers. When dazmegrel was orally administered to greyhound dogs wearing leg casts, it resulted in a sparring effect on the skin areas of potential pressure ulcer development. The objective of this research was to determine if bioelastic matrices could provide controlled release of thromboxane A2 synthetase inhibitor (dazmegrel) at tissue concentrations sufficient for inhibition of thromboxane synthesis. The animal used for these studies was the greyhound, which has thin skin, angular conformation, limited body fat and is predisposed to pressure ulcers similar to those occurring in humans. In vivo skin penetration studies showed that epidermal exposure to bioelastic thromboxane synthetase inhibitor (TSI) matrix resulted in local tissue concentrations of TSI sufficient for thromboxane synthetase inhibition. There were no significant differences between dazmegrel in the skin layers (epidermis, dermis and subcutaneous layers) on 1, 7 and 14-day exposures.

Elastin: a representative ideal protein elastomer.

During the last half century, identification of an ideal (predominantly entropic) protein elastomer was generally thought to require that the ideal protein elastomer be a random chain network. Here, we report two new sets of data and review previous data. The first set of new data utilizes atomic force microscopy to report single-chain force-extension curves for (GVGVP)(251) and (GVGIP)(260), and provides evidence for single-chain ideal elasticity. The second class of new data provides a direct contrast between low-frequency sound absorption (0.1-10 kHz) exhibited by random-chain network elastomers and by elastin protein-based polymers. Earlier composition, dielectric relaxation (1-1000 MHz), thermoelasticity, molecular mechanics and dynamics calculations and thermodynamic and statistical mechanical analyses are presented, that combine with the new data to contrast with random-chain network rubbers and to detail the presence of regular non-random structural elements of the elastin-based systems that lose entropic elastomeric force upon thermal denaturation. The data and analyses affirm an earlier contrary argument that components of elastin, the elastic protein of the mammalian elastic fibre, and purified elastin fibre itself contain dynamic, non-random, regularly repeating structures that exhibit dominantly entropic elasticity by means of a damping of internal chain dynamics on extension.

Mechanics of elastin: molecular mechanism of biological elasticity and its relationship to contraction.

Description of the mechanics of elastin requires the understanding of two interlinked but distinct physical processes; the development of entropic elastic force and the occurrence of hydrophobic association. Elementary statistical-mechanical analysis of AFM single-chain force-extension data of elastin model molecules identifies damping of internal chain dynamics on extension as a fundamental source of entropic elastic force and eliminates the requirement of random chain networks. For elastin and its models, this simple analysis is substantiated experimentally by the observation of mechanical resonances in the dielectric relaxation and acoustic absorption spectra, and theoretically by the dependence of entropy on frequency of torsion-angle oscillations, and by classical molecular-mechanics and dynamics calculations of relaxed and extended states of the beta-spiral description of the elastin repeat, (GVGVP)n. The role of hydrophobic hydration in the mechanics of elastin becomes apparent under conditions of isometric contraction. During force development at constant length, increase in entropic elastic force resulting from decrease in elastomer entropy occurs under conditions of increase in solvent entropy. This eliminates the solvent entropy change as the entropy change that gives rise to entropic elastic force and couples association of hydrophobic domains to the process. Therefore, association of hydrophobic domains within the elastomer at fixed length stretches interconnecting dynamic chain segments and causes an increase in the entropic elastic force due to the resulting damping of internal chain dynamics. Fundamental to the mechanics of elastin is the inverse temperature transition of hydrophobic association that occurs with development of mechanical resonances within fibrous elastin and polymers of repeat elastin sequences, which, with design of truly minimal changes in sequence, demonstrate energy conversions extant in biology and demonstrate the special capacity of bound phosphates to raise the free energy of hydrophobic association.

Elastomeric polypentapeptides cross-linked into matrixes and fibers.

Microbially prepared polypentapeptides were cross-linked by two chemical methods. In one chemical approach, (GVGIP)(260) where G = glycine, V = valine, I = isoleucine, and P = proline with no functional groups in its side chains, was cross-linked using dicumyl peroxide, and reaction conditions were systematically examined. Successful cross-linking was obtained even under severe conditions for proteins, i.e., 3 h at 120 degrees C, without having significant side reactions. In the second chemical approach, two separate polymers, (GVGVP GVGVP GXGVP GVGVP GVGVP GVGVP)(n) where X is either E (the carboxylic acid containing glutamic acid residue) or K (the lysine residue with an epsilon-amino function), were mixed and cross-linked using a carbodiimde reagent. The reaction temperature was found to affect the equilibrium swelling behavior of the resulting cross-linked hydrogels. In hydrogels cross-linked at a temperature above their hydrophobic folding and assembling transition temperature, 3D continuous filamentous microstructures were observed. Chemically cross-linked hydrogel fibers were also prepared and their anisotropy in swelling was confirmed. Uniaxial tensile moduli and equilibrium weight swelling ratios of the chemically cross-linked samples were compared to those of (GVGVP)(251) and (GVGIP)(260), gamma-irradiation cross-linked at different Mrad doses.

Wheat seed proteins exhibit a complex mechanism of protein elasticity.

Elastomeric proteins are found in a number of animal tissues (elastin, abductin and resilin), where they have evolved to fulfil a range of biological functions. All exhibit rubber-like elasticity, undergoing deformation without rupture, storing the energy involved in deformation, and then recovering to their initial state when the stress is removed. The second part of the process is passive, entropy decreasing when the proteins are deformed, with the higher entropy of the relaxed state providing the driving force for recoil. In plants there is only one well-documented elastomeric protein system, the alcohol-soluble seed storage proteins (gluten) of wheat. The elastic properties of these proteins have no known biological role, the proteins acting as a store for the germinating seed. Here we show that the modulus of elasticity of a group of wheat gluten subunits, when cross-linked by gamma-radiation, is similar to that of the cross-linked polypentapeptide of elastin. However, thermoelasticity studies indicate that the mechanism of elastic recoil is different from elastin and other characterized protein elastomers. Elastomeric force, f, has two components, an internal energy component, f(e), and an entropic component, f(s). The ratio f(e)/f can be determined experimentally; if this ratio is less than 0.5 the elastomeric force is predominantly entropic in origin. The ratio was determined as 5.6 for the cross-linked high M(r) subunits of wheat glutenin and near zero for the cross-linked polypentapeptide of elastin. Tensile stress must be entropic or energetic in origin, the results would suggest that elastic recoil in the wheat gluten subunits, in part, may be associated with extensive hydrogen bonding within and between subunits and that entropic and energetic mechanisms contribute to the observed elasticity.

Phase transition and elasticity of protein-based hydrogels.

Reported are specific materials characterizations of three protein-based polymers comprised of repeating pentapeptide sequences, namely (GVGVP)251, (GVGIP)260 and (GVGVP GVGVP GEGVP GVGVP GVGVP GVGVP)n](GVGVP) where G = glycine, V = valine, P = proline, I = isoleucine, and E = glutamic acid, which had been previously prepared and gamma-irradiation cross-linked into elastic matrices. These polymers exhibit a hydrophobic folding and assembling transition on raising the temperature above a critical temperature, designated by Tt. Their equilibrium swelling ratio, uniaxial tensile and dynamic shear behavior were studied. The effect of the transition on swelling and mechanical properties was demonstrated. Equilibrium swelling ratio below the transition temperature decreased with the increase of gamma-irradiation dose. Above the transition temperature, hysteresis and frequency dependence were found in tensile loading-unloading tests and dynamic shear measurements, respectively. The rubber elasticity theory of random chain networks was applied to the data only below the transition temperature, where they may properly be considered random network hydrogels, to estimate molecular weight between cross-links and the Flory-Huggins interaction parameter.

Interaction of processes on different length scales in a bioelastomer capable of performing energy conversion.

This work concerns the aggregation properties of (Gly-Val-Gly-Val-Pro)(251) rec, a polypentapeptide reflecting a highly conserved repetitive unit of the bioelastomer, elastin. On raising the temperature of aqueous solutions above 25 degrees C, this polypeptide was already known to undergo concurrent conformational changes (hydrophobic folding), phase separation, and self-assembly with formation of aggregated three-stranded filaments composed of dynamic polypeptide helices, called beta-spirals. Aggregates obtained from the solution can be shaped into bands that acquire entropic elastic properties upon gamma-irradiation and can perform a variety of energy conversions. Previous studies have shown that aggregation is prompted by the (diverging) critical fluctuations of concentration occurring in the solution, in vicinity of its spinodal line. Here, we present combined circular dicroism (CD) and light scattering experiments, and independent fittings of experimental data to the theoretical spinodal and binodal (coexistence) lines. Results show the following logical and causal sequence of processes: (a) Smooth and progressive conformational changes promoted by concentration fluctuations occurring as temperature is raised "pull down" (in the temperature scale) the instability region of the solution. (b) This further promotes critical fluctuations. (c) The related locally high concentration prompts a further substantial conformational change ending in triple-helix formation and coacervation. (d) This intertwining of processes, covering different length scales (from that of individual peptides to the mesoscopic one of demixed regions), is related to the fact that solvent-induced interactions play a strong role over the entire scale span. These results concur with other recent ones in pointing out that process interactions over many length-scales probably reflect a frequent if not ubiquitous pattern in protein aggregation. This may be highly relevant to the desirable deep understanding of such phenomenon, whose interests cover many fields.

Elastic molecular machines in metabolism and soft-tissue restoration.

Elastic protein-based machines (bioelastic materials) can be designed to perform diverse biological energy conversions. Coupled with the remarkable energy-conversion capacity of cells, this makes possible a tissue-restoration approach to tissue engineering. When properly attached to the extracellular matrix, cells sense the forces to which they are subjected and respond by producing an extracellular matrix that will withstand those forces. Elastic protein-based polymers can be designed as temporary functional scaffoldings that cells can enter, attach to, spread, sense forces and remodel, with the potential to restore natural tissue.

Elastic protein-based polymers in soft tissue augmentation and generation.

Five elastic protein-based polymers, designed as variations of polymer I, (GVGVP)251, elicited different responses when injected as subcutaneous implants in the guinea pig, a preclinical test used to evaluate materials for soft tissue augmentation and specifically for correction of urinary incontinence. All six polymers, prepared using recombinant DNA technology, expressed at good levels using transformed E. coli fermentation. These E. coli-produced polymers were purified for the first time to the exacting levels required for use as biomaterials where a large quantity could disperse into the tissues in a few days. Time periods of 2 and 4 weeks were used. Polymer I functioned as a bulking agent around which a fine fibrous capsule formed. Inclusion of (GVGVAP)8, a chemoattractant toward monocytes and elastin-synthesizing fibroblasts in the sequence of polymer I, resulted in an appropriate tissue response of invasion of macrophages. Inclusion of lysine residues, for lysyl oxidase cross-linking, suggested a possible remodeling of the implant toward fibers. Most promising however, when the cell attachment sequence, GRGDSP, was added to polymer I, the implant elicited tissue generation with a normal complement of collagen and elastic fibers, spindle-shaped histiocytes and angiogenesis. If this response is retained over time, the desired soft tissue augmentation and generation will have been achieved. Our working hypothesis is that on formation of elastin, with a half-life of the order of 70 years, a long lasting soft tissue augmentation would result rather than scar tissue as occurs with Contigen, the currently approved injectable implant for soft tissue augmentation.

Expression of a synthetic protein-based polymer (elastomer) gene in Aspergillus nidulans.

A gene for a synthetic protein-based polymer, G-(VPGVG)119-VPGV, coding for the EG-120mer (elastomer), was cloned into a fungal expression vector to allow constitutive expression of the polymer controlled by the gpdA (glyceraldehyde-3-phosphate dehydrogenase) promoter sequence of Aspergillus nidulans. Stable transformants of A. nidulans showed plasmid integration with varying copy number when analyzed by Southern-blot hybridization. Expression of the synthetic gene was demonstrated by Northern-blot hybridization. However, the translational efficiency for production of the polymer polypeptide was low, presumably because of certain codons in the polymer gene (CCG and GUA) that are rarely used by A. nidulans. Partial purification by reversible phase transition followed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed the presence of polymer protein in a transformant that contained multiple copies of the polymer gene. This study represents the first attempt to express a synthetic gene (with no natural analog) in a fungus.

Elastic protein-based materials in tissue reconstruction.

In natural tissues, cells form multiple attachment sites to their extracellular matrix. By means of those attachments, cells deform as the tissue deforms in response to the natural mechanical stresses and strains that the tissue must sustain during function. These mechanical forces are the energy input that instruct the cells to produce the extracellular matrix sufficient to sustain those forces. Thus, an ideal artificial material should have both the attachment sites for the natural cells and a compliance that matches the natural tissue. Elastic protein-based polymers have been designed to provide both cell attachment sites and to exhibit the required elastic modulus of the tissue to be replaced. Thus, this introduces the potential to design a temporary functional scaffolding that will be remodeled, while functioning, into a natural tissue. A feasibility study applies this concept to the problem of urinary bladder reconstruction in terms of the filling and emptying of a simulated bladder comprised of an elastic protein-based matrix containing cell attachment sites with human urothelial cells growing out onto the dynamic matrix. Furthermore, the elastic protein-based materials themselves have been designed to perform the set of energy conversions that occur in living organisms and, in particular, to convert mechanical energy into chemical energy with the result of chemical signals of the sort that could provide the stimuli to turn on the genes for producing the required extracellular proteins.

Product purification by reversible phase transition following Escherichia coli expression of genes encoding up to 251 repeats of the elastomeric pentapeptide GVGVP.

By constructing a basic gene unit encoding (GVGVP)10, it was possible to build concatemer genes with as many as 25 repeats of the monomer unit encoding a protein-based polymer with a molecular weight of greater than 100,000 Da. This employed the use of terminal cloning adaptor oligonucleotides as chain terminators to enhance the desired polymer gene size distribution. These genes have been expressed in Escherichia coli and the products have been purified from the culture lysates using a simple centrifugation method which relies upon the inverse temperature transitional properties of these elastomeric protein-based polymers. At 4 degrees C, the polymers are soluble; on raising the temperature above 26 degrees C, the onset temperature (Tt) for the (GVGVP)251 inverse temperature transition, the polymer separates out as the more dense phase. Upon shifting the temperature between 4 and 37 degrees C, the recombinant elastomeric protein-based polymers undergo reversible phase transitions from soluble (4 degrees C) to insoluble (37 degrees C) allowing their separation from other cellular components by several cycles of centrifugations at alternate transitional states. Additional centrifugation, at a temperature just below Tt, allows for dramatic lowering of endotoxin levels. Furthermore, many ways of varying the value of Tt, such as adding salt to lower Tt or changing the degree of ionization in polymers with functional side chains, can be used to achieve purification of more complex polymers.

Expression of an environmentally friendly synthetic protein-based polymer gene in transgenic tobacco plants.

We report the expression of a protein-based polymer (Gly-Val-Gly-Val-Pro)121, i. e., (GVGVP)121 in transgenic tobacco (Nicotiana tabacum var. Kentucky 17) plants. The plant expression vector pBI121-XZ-120mer which contains the gene (GVGVP)121 with a prokaryotic preferred codon composition driven by the CaMV 35S promoter was introduced into tobacco plants byAgrobacterium-mediated transformation. Stable integration of the (GVGVP)121 polymer gene was confirmed by Southern blot analysis. Northern hybridization showed polymer transcripts in leaves of transgenic plants. The (GVGVP)121 polymer protein was detected in leaves of transgenic plants by Western blot. The (GVGVP)121 protein could be easily purified to a high degree of purity from leaves of transgenic plants by reversible phase transition as revealed by SDS-PAGE gels stained by CuCl2. Transgenic plants grew, flowered, and produced seeds normally.

Synthesis and characterization of the human elastin W4 sequence.

Following the nomenclature of Sandberg, the W4 sequence of human elastin, [sequence: see text], has been synthesized by solid-phase methods and characterized by carbon-13 nuclear magnetic resonance, amino-acid analysis, mass spectra and elemental analysis. This sequence was then polymerized to greater than 50 kDa as determined by retention in 50 kDa molecular weight cut-off dialysis tubing. It has been successfully cross-linked by gamma-irradiation (20 Mrad) to form an elastomeric matrix, designated as X20-poly(W4). Physical characterizations such as stress/strain, thermolelasticity, acid-base titration and inverse temperature transition studies have been carried out on this elastomer, which is homologous to the striking, poly(VPGVG), W4 sequence of bovine and porcine elastins. These results are compared with previous results on the polypentapeptide of elastin, (VPGVG)n, and it has been demonstrated that X20-poly(W4) also is a dominantly entropic elastomer. Finally, the working model for the structure of this human elastin sequence was derived computationally using molecular mechanics and dynamics calculations. Thus the human W4 sequence appears to be structurally and functionally equivalent to the bovine and porcine W4 sequences in spite of the less regular repeating pentamer sequence.

The determination of binding constants of micellar-packaged gramicidin A by 13C-and 23Na-NMR.

Based on the malonyl gramicidin A structure of a single-stranded head-to-head hydrogen bonded right-handed, beta 6.3-helix in dodecyl phosphocholine (DPC) lipid micelles (Jing et al. (1994) Biophys. J. 66, A353), the determination of cation binding sites for gramicidin A (GA) in DPC micelles becomes a significant step in the study of ion transport through the model channel. First, the investigation of cation binding sites in DPC micellar packaged gramicidin A was achieved by 13C-NMR experiments at 30 degrees C using four C-13 labeled GA samples. Then, the analyses based on two different equations, one for single and one for double occupancy, were employed to evaluate the correct occupancy model for GA in DPC micelles. The results clearly indicate double occupancy to be correct for Na+ ion as well as for K+, Rb+, Cs+, and Tl+ ions. Finally, the binding constants for Na+ ion were also estimated by the measurement of the longitudinal relaxation time (T1) using 23Na-NMR of the same sample at the same ffmperature as used for the 13C-NMR study. The binding constants obtained from 23Na-NMR are essentially equivalent to those determined from the 13C-chemical shifts.

Ion pair binding of Ca2+ and Cl- ions in micellar-packaged gramicidin A.

The two independent NMR experiments were performed to investigate the interaction between CaCl2 and the gramicidin A (GA) ion transport channel, using 13C-enriched GA and GA molecules incorporated into dodecylphosphocholine (DPC) micelles. The chemical shifts of C-13 labeled carbonyl carbons vs. CaCl2 concentration demonstrate that Ca2+ and Cl- ions interact as an ion pair within the GA structure with the Cl- ion located near the position of the carbonyl group of the Trp11 residue some 5.5 A from the mouth of the GA helix, and the Ca2+ ion bound at the position of the carbonyl group of the Trp15 residue some 2.5 A from the entrance to the helical pore. The measurements of the 35Cl line-widths and transverse relaxation times illustrate that the interaction occurs between Cl- ions and GA in DPC when in CaCl2 solution, that no interaction is detected between Cl- ions and GA in DPC when in NaCl solution, and that the interaction between Cl- ions and GA in DPC when in MgCl2 solution is much weaker than in CaCl2 solution. In short, a Cl- ion can enter the GA when it is paired with a divalent Ca2+ ion; and Ca2+ and Cl- ions as a pair exchange rapidly with sites of the GA dimer.

Electro-chemical transduction in elastic protein-based polymers: a model for an energy conversion step of oxidative phosphorylation.

A pair of functional moieties, the carboxyl of an aspartic acid (Asp, D) residue and an N-methyl nicotinamide (NMeN) formed on amide linkage to the epsilon-amino group of the lysine (Lys, K) residue, are coupled to perform energy conversion by means of controlling the transition temperature, Tt, of a common hydrophobic folding and assembly domain within the polytricosapeptide, poly[GDGFP GVGVP GVGVP GFGVP GVGVP GVGK(NMeN)P]. The input of electrochemical energy in the form of the reduction of nicotinamide results in a reduction-induced increase in pKa by 2.5 pH units which represents the performance of the chemical work of picking up a proton. The primary structure and the structures of the oxidized and reduced states are verified by two-dimensional nuclear magnetic resonance. Thus electrochemical transduction, the conversion of electrochemical energy into chemical energy, has been demonstrated for the first time in a designed, synthetic protein-based polymer.

Molecular biophysics of elastin structure, function and pathology.

Owing to the presence of the recurring sequence XPGX' (where X and X' are hydrophobic residues), the molecular structure of the sequences between cross-links in elastin is viewed primarily as a series of beta-turns which become helically ordered by hydrophobic folding into beta-spirals, which in turn assemble hydrophobically into twisted filaments. Both hydrophobic folding and assembly occur when the temperature is raised above Tt, the onset of an inverse temperature transition. Using poly[fv(VPGVG),fx(VPGXG)] (where fv and fx are mole fractions with fv + fx = 1 and X is now any of the naturally occurring amino acid residues), plots of fx versus Tt result in a new hydrophobicity scale based directly on the hydrophobic folding and assembly processes of interest. With the reference values chosen at fx = 1, the most hydrophobic residues of elastin, Tyr (Y) and Phe (F), have low values of Tt, -55 and -30 degrees C, respectively, and the most hydrophilic residues, Glu (E-), Asp (D-) and Lys (K+), have high values of 250, 170 and 120 degrees C, respectively. Raising the average value of Tt for a chain or chain segment from below to above physiological temperature drives hydrophobic unfolding and disassembly; lowering Tt does the reverse. This delta Tt mechanism has been used reversibly to interconvert many energy forms and is used here to explain initiating events of elastogenesis, pulmonary emphysema, solar elastosis and the paucity of elastic fibres in scar tissue. In general, oxidation and/or photolysis convert(s) hydrophobic residues into polar residues with the consequences of irreversibly raising Tt to above 37 degrees C, hydrophobic unfolding and disassembly (fibre swelling), and greater susceptibility to proteolysis.