Engineering of methionine-auxotroph Escherichia coli via parallel evolution of two enzymes from Corynebacterium glutamicum's direct-sulfurylation pathway enables its recovery in minimal medium.

Methionine biosynthesis relies on the sequential catalysis of multiple enzymes. Escherichia coli, the main bacteria used in research and industry for protein production and engineering, utilizes the three-step trans-sulfurylation pathway catalyzed by L-homoserine O-succinyl transferase, cystathionine gamma synthase and cystathionine beta lyase to convert L-homoserine to L-homocysteine. However, most bacteria employ the two-step direct-sulfurylation pathway involving L-homoserine O-acetyltransferases and O-acetyl homoserine sulfhydrylase. We previously showed that a methionine-auxotroph Escherichiacoli strain (MG1655) with deletion of metA, encoding for L-homoserine O-succinyl transferase, and metB, encoding for cystathionine gamma synthase, could be complemented by introducing the genes metX, encoding for L-homoserine O-acetyltransferases and metY, encoding for O-acetyl homoserine sulfhydrylase, from various sources, thus altering the Escherichia coli methionine biosynthesis metabolic pathway to direct-sulfurylation. However, introducing metX and metY from Corynebacterium glutamicum failed to complement methionine auxotrophy. Herein, we generated a randomized genetic library based on the metX and metY of Corynebacterium glutamicum and transformed it into a methionine-auxotrophic Escherichia coli strain lacking the metA and metB genes. Through multiple enrichment cycles, we successfully isolated active clones capable of growing in M9 minimal media. The dominant metX mutations in the evolved methionine-autotrophs Escherichia coli were L315P and H46R. Interestingly, we found that a metY gene encoding only the N-terminus 106 out of 438 amino acids of the wild-type MetY enzyme is functional and supports the growth of the methionine auxotroph. Recloning the new genes into the original plasmid and transforming them to methionine auxotroph Escherichia coli validated their functionality. These results show that directed enzyme-evolution enables fast and simultaneous engineering of new active variants within the Escherichia coli methionine direct-sulfurylation pathway, leading to efficient complementation.

Endotoxin-free gram-negative bacterium as a system for production and secretion of recombinant proteins.

Gram-negative bacteria are common and efficient protein expression systems, yet their outer membrane endotoxins can elicit undesirable toxic effects, limiting their applicability for parenteral therapeutic applications, e.g., production of vaccine components. In the bacterial genus Sphingomonas from the Alphaproteobacteria class, lipopolysaccharide (LPS) endotoxins are replaced with non-toxic glycosphingolipids (GSL), rendering it an attractive alternative for therapeutic protein production. To explore the use of sphingomonas as a safe expression system for production of proteins for therapeutic applications, in this study, Sphingobium japonicum (SJ) injected live into embryonated hen eggs proved safe and nontoxic. Multimeric viral polypeptides derived from Newcastle disease virus (NDV) designed for expression in SJ, yielded soluble proteins which were specifically recognized by antibodies raised against the whole virus. In addition, native signal peptide (SP) motifs coupled to secreted proteins in SJ identified using whole-genome computerized analysis, induced secretion of α Amylase (αAmy) and mCherry gene products. Relative to the same genes expressed without an SP, SP 104 increased the secretion of αAmy (3.7-fold) and mCherry (16.3-fold) proteins and yielded accumulation of up to 80 µg/L of the later in the culture medium. Taken together, the presented findings demonstrate the potential of this unique LPS-free gram-negative bacterial family to serve as an important tool for protein expression for both research and biotechnological purposes, including for the development of novel vaccines and as a live bacteria delivery system for protein vaccines. KEY POINTS: • Novel molecular tools for protein expression in non-model bacteria. • Bacteria with GSL instead of LPS as a potential vector for protein delivery.

Protection against avian coronavirus conferred by oral vaccination with live bacteria secreting LTB-fused viral proteins.

The devastating impact of infectious bronchitis (IB) triggered by the IB virus (IBV), on poultry farms is generally curbed by livestock vaccination with live attenuated or inactivated vaccines. Yet, this approach is challenged by continuously emerging variants and by time limitations of vaccine preparation techniques. This work describes the design and evaluation of an anti-IBV vaccine comprised of E. coli expressing and secreting viral spike 1 subunit (S1) and nucleocapsid N-terminus and C-terminus polypeptides fused to heat-labile enterotoxin B (LTB) (LS1, LNN, LNC, respectively). Following chicken oral vaccination, anti-IBV IgY levels and cellular-mediated immunity as well as protection against virulent IBV challenge, were evaluated 14 days following the booster dose. Oral vaccination induced IgY levels that exceeded those measured following vaccination with each component separately. Following exposure to inactivated IBV, splenocytes isolated from chicks orally vaccinated with LNN or LNC -expressing bacteria, showed a higher percentage of CD8+ cells as compared to splenocytes isolated from chicks vaccinated with wild type or LTB-secreting E. coli and to chicks subcutaneously vaccinated. Significant reduction in viral load and percent of shedders in the vaccinated chicks was evident starting 3 days following challenge with 107.5 EID50/ml virulent IBV. Taken together, orally delivered LTB-fused IBV polypeptide-expressing bacteria induced virus-specific IgY antibody production and was associated with significantly shorter viral shedding on challenge with a live IBV. The proposed vaccine design and delivery route promise an effective and rapidly adaptable means of protecting poultry farms from devastating IB outbreaks.

Inhibition of PD1:PD-L1 interaction by an E. coli-derived optimized PD1 variant.

Immune-checkpoint receptors are a set of signal transduction proteins that can stimulate or inhibit specific anti-tumor responses. It is well established that cancer cells interact with different immune checkpoints to shut down T-cell response, thereby enabling cancer proliferation. Given the importance of immune checkpoint receptors, a structure-function analysis of these systems is imperative. However, recombinant expression and purification of these membrane originated proteins is still a challenge. Therefore, many attempts are being made to improve their expression and solubility while preserving their biological relevance. For this purpose, we designed an E. coli-based optimization system that enables the acquisition of mutations that increases protein solubility and affinity towards its native ligand, while maintaining biological activity. Here we focused on the well-characterized extracellular domain of the 'programmed cell death protein 1' (PD1), an immune checkpoint receptor known to inhibit T-cell proliferation by interacting with its ligands PD-L1 and PD-L2. The simple ELISA-based screening system shown here enabled the identification of high-affinity, highly soluble, functional variants derived from the extracellular domain of human PD1. The system was based on the expression of a GST-tagged variants library in E. coli, which enabled the selection of improved PD1 variants after a single optimization round. Within only two screening rounds, the most active variant showed a 5-fold higher affinity and 2.4-fold enhanced cellular activity as compared to the wild type protein. This scheme can be translated toward other types of challenging receptors toward development of research tools or alternative therapeutics.

De Novo Evolutionary Emergence of a Symmetrical Protein Is Shaped by Folding Constraints.

Molecular evolution has focused on the divergence of molecular functions, yet we know little about how structurally distinct protein folds emerge de novo. We characterized the evolutionary trajectories and selection forces underlying emergence of ß-propeller proteins, a globular and symmetric fold group with diverse functions. The identification of short propeller-like motifs (<50 amino acids) in natural genomes indicated that they expanded via tandem duplications to form extant propellers. We phylogenetically reconstructed 47-residue ancestral motifs that form five-bladed lectin propellers via oligomeric assembly. We demonstrate a functional trajectory of tandem duplications of these motifs leading to monomeric lectins. Foldability, i.e., higher efficiency of folding, was the main parameter leading to improved functionality along the entire evolutionary trajectory. However, folding constraints changed along the trajectory: initially, conflicts between monomer folding and oligomer assembly dominated, whereas subsequently, upon tandem duplication, tradeoffs between monomer stability and foldability took precedence.

Functional ß-propeller lectins by tandem duplications of repetitive units.

Internal symmetry in proteins is likely to be the footprint of evolution by gene duplication and fusion. Like other symmetrical proteins, ß-propellers, which are made of 4-10 ß-sheet units (blades) circularly arranged around a central tunnel, have probably evolved by duplication and fusion of a rudimentary repetitive unit. However, reproducing the evolution of functional ß-propellers by duplication and fusion of repeated units remains a challenge, in particular, because the repeated units must jointly pack to form one hydrophobic core while maintaining intact active sites. As model for generating repeat propellers, we chose tachylectin-2--a highly symmetrical five-bladed ß-propeller lectin with five sugar-binding sites. We report the engineering of folded and functional lectins by duplication and fusion of repetitive sequence modules taken from tachylectin-2. The repeated modules comprise three strands of one blade plus one strand of the next blade, thus enabling the closure of the propeller's ring via strand-strand Velcro-like interactions. Duplication and fusion of five modules with the same sequence gave rise to a highly aggregated protein, yet its soluble fraction exhibited lectin function. Subsequently, a library of diversified sequence modules fused in tandem was selected by phage display for glycoprotein binding. A range of new lectins were isolated with binding and biophysical properties that resemble those of wild-type tachylectin-2. These results demonstrate the ability to construct folded and functional globular repeat proteins, and support the role of duplication and fusion of elementary modules in the evolutionary routes that led to the ß-propellers fold.

Reconstruction of functional beta-propeller lectins via homo-oligomeric assembly of shorter fragments.

The modular nature of protein folds suggests that present day proteins evolved via duplication and recombination of smaller functional elements. However, the reconstruction of these putative evolutionary pathways after many millions of years of evolutionary drift has thus far proven difficult, with all attempts to date failing to produce a functional protein. Tachylecin-2 is a monomeric 236 amino acid, five-bladed beta-propeller with five sugar-binding sites. This protein was isolated from a horseshoe crab that emerged ca 500 million years ago. The modular, yet ancient, nature of Tachylectin-2 makes it an excellent model for exploring the evolution of proteins from smaller subunits. To this end, we generated genetically diverse libraries by incremental truncation of the Tachylectin-2 gene and screened them for functional lectins. A number of approximately 100 amino acid residue segments were isolated with the ability to assemble into active homo-pentamers. The topology of most of these segments follows a "hidden" module that differs from the modules observed in wild-type Tachylectin-2, yet their biophysical properties and sugar binding activities resemble the wild-type's. Since the pentamer's molecular mass is twofold higher than the wild-type (approximately 500 amino acid residues), the structure of these oligomeric forms is likely to also differ. Our laboratory evolution experiments highlight the versatility and modularity of the beta-propeller fold, while substantiating the hypothesis that proteins with high internal symmetry, such as beta-propellers, evolved from short, functional gene segments that, at later stages, duplicated, fused, and rearranged, to yield the folds we recognise today.