Synthesis of bioengineered heparin chemically and biologically similar to porcine-derived products and convertible to low MW heparin.

Heparins have been invaluable therapeutic anticoagulant polysaccharides for over a century, whether used as unfractionated heparin or as low molecular weight heparin (LMWH) derivatives. However, heparin production by extraction from animal tissues presents multiple challenges, including the risk of adulteration, contamination, prion and viral impurities, limited supply, insecure supply chain, and significant batch-to-batch variability. The use of animal-derived heparin also raises ethical and religious concerns, as well as carries the risk of transmitting zoonotic diseases. Chemoenzymatic synthesis of animal-free heparin products would offer several advantages, including reliable and scalable production processes, improved purity and consistency, and the ability to produce heparin polysaccharides with molecular weight, structural, and functional properties equivalent to those of the United States Pharmacopeia (USP) heparin, currently only sourced from porcine intestinal mucosa. We report a scalable process for the production of bioengineered heparin that is biologically and compositionally similar to USP heparin. This process relies on enzymes from the heparin biosynthetic pathway, immobilized on an inert support and requires a tailored N-sulfoheparosan with N-sulfo levels similar to those of porcine heparins. We also report the conversion of our bioengineered heparin into a LMWH that is biologically and compositionally similar to USP enoxaparin. Ultimately, we demonstrate major advances to a process to provide a potential clinical and sustainable alternative to porcine-derived heparin products.

Efficient identification of compounds suppressing protein precipitation via solvent screening using serial deletion mutants of the target protein.

The control of protein solubility is a subject of broad interest. Although several solvent screening methods are available to search for compounds that enhance protein solubilization, their performance is influenced by the intrinsic solubility of the tested protein. We now present a method for screening solubilizing compounds, using an array of N- or C-terminal deletion mutants of the protein. A key behind this approach is that such terminal deletions of the protein affect its aggregation propensity. The solubilization activities of trial solvents are individually assessed, based on the number of solubilized mutants. The solubilizing compounds are then identified from the screened solvents. In this study, the C-terminal chemokine receptor-binding region of the cytoplasmic protein, FROUNT (FNT-C), which mediates intracellular signals leading to leukocyte migration, was subjected to the multicomponent screening. In total, 192 solution conditions were tested, using eight terminal deletion mutants of FNT-C. We identified five solvent conditions that solubilized four or five mutants of FNT-C, and the compounds in the screened solvents were then, respectively, assessed in terms of their solubilization ability. The best compound for solubilizing FNT-C was 1,6-hexanediol. Indeed, 1,6-hexanediol bound to FNT-C and suppressed its precipitation, as showed by NMR and dynamic light scattering analyses.

Enzymatic Generation of Highly Anticoagulant Bovine Intestinal Heparin.

Unlike USP porcine heparin, bovine intestinal heparin (BIH) has a low anticoagulant activity. Treatment with 6-OST-1, -3, and/or 3-OST-1 afforded two remodeled heparins that met USP heparin activity and Mw specifications. We explored the pharmacodynamics and pharmacokinetics in a rabbit model. We conclude that a modest increase in the content of 3-O-sulfo groups in BIH increases the number of antithrombin III binding sites, making remodeled BIH behave similarly to pharmaceutical heparin.

Structural and activity variability of fractions with different charge density and chain length from pharmaceutical heparins.

Heparin is a structurally complex polysaccharide used as a clinical anticoagulant. It is comprised of a heterogeneous mixture of polysaccharide chains having a variety of sequences and lengths. The production methods and regulatory controls of pharmaceutical heparins have changed over the years. This study assesses the structural and activity uniformity of the polysaccharide chains comprising two contemporary heparin products. The heparin fractions with different sizes and charges were separated with size exclusion and ion exchange chromatography. The fractions were analyzed for their molecular weight properties, di- and tetrasaccharide compositions, and anti-factor IIa and anti-factor-Xa activities. The distribution of these properties through chains of different lengths and ones with different charge density were compared. The results demonstrate that with the increase in heparin purity, activity and molecular weight required by the current pharmacopeia, the uniformity of pharmaceutical heparin products have increased.

Expression and purification of mouse peptide ESP4 in Escherichia coli.

Pheromones are species-specific chemical signals that regulate a wide range of social and sexual behaviors in many animals. In mice, the male-specific peptide ESP1 (exocrine gland-secreting peptide 1) is secreted into tear fluids and enhances female sexual receptive behavior. ESP1 belongs to the ESP family, a multigene family with 38 genes in mice. ESP1 shares the highest homology with ESP4. ESP1 is expressed in the extraorbital lacrimal gland, whereas ESP4 is expressed in some exocrine glands. Thus, ESP4 is expected to have a function that has not been elucidated yet. Large amounts of the purified ESP4 protein are required for structural and biochemical studies. Here we present an expression and purification scheme for the recombinant ESP4 protein. The N-terminally histidine-tagged ESP4 fusion protein was expressed in Escherichia coli as inclusion bodies, which were solubilized and purified by nickel affinity chromatography. The histidine tag was cleaved with thrombin and removed by a second nickel affinity chromatography step. The ESP4 protein was isolated with high purity by reversed-phase chromatography. For NMR analyses, we prepared a stable isotope-labeled ESP4 protein. Three repeated freeze-drying steps after the reversed-phase chromatography were required, to remove a volatile contaminating compound and to obtain an NMR spectrum with a homogeneous line shape. AMS-modification and far-UV CD spectroscopic analyses suggested that ESP4 has an intramolecular disulfide bridge and a helical structure, respectively. The present study provides a powerful tool for structural and biochemical studies of ESP4, leading toward the elucidation of the roles of the ESP family members.

Structure of the mouse sex peptide pheromone ESP1 reveals a molecular basis for specific binding to the class C G-protein-coupled vomeronasal receptor.

Exocrine gland-secreting peptide 1 (ESP1) is a sex pheromone that is released in male mouse tear fluids and enhances female sexual receptive behavior. ESP1 is selectively recognized by a specific class C G-protein-coupled receptor (GPCR), V2Rp5, among the hundreds of receptors expressed in vomeronasal sensory neurons (VSNs). The specific sensing mechanism of the mammalian peptide pheromone by the class C GPCR remains to be elucidated. Here we identified the minimal functional region needed to retain VSN-stimulating activity in ESP1 and determined its three-dimensional structure, which adopts a helical fold stabilized by an intramolecular disulfide bridge with extensive charged patches. We then identified the amino acids involved in the activation of VSNs by a structure-based mutational analysis, revealing that the highly charged surface is crucial for the ESP1 activity. We also demonstrated that ESP1 specifically bound to an extracellular region of V2Rp5 by an in vitro pulldown assay. Based on homology modeling of V2Rp5 using the structure of the metabotropic glutamate receptor, we constructed a docking model of the ESP1-V2Rp5 complex in which the binding interface exhibited good electrostatic complementarity. These experimental results, supported by the molecular docking simulations, reveal that charge-charge interactions determine the specificity of ESP1 binding to V2Rp5 in the large extracellular region characteristic of class C GPCRs. The present study provides insights into the structural basis for the narrowly tuned sensing of mammalian peptide pheromones by class C GPCRs.