Engineering of TEV protease variants with redesigned substrate specificity.

Due to their ability to catalytically cleave proteins and peptides, proteases present unique opportunities for the use in industrial, biotechnological, and therapeutic applications. Engineered proteases with redesigned substrate specificities have the potential to expand the scope of practical applications of this enzyme class. We here apply a combinatorial protease engineering-based screening method that links proteolytic activity to the solubility and correct folding of a fluorescent reporter protein to redesign the substrate specificity of tobacco etch virus (TEV) protease. The target substrate EKLVFQA differs at three out of seven positions from the TEV consensus substrate sequence. Flow cytometric sorting of a semi-rational TEV protease library, consisting of focused mutations of the substrate binding pockets as well as random mutations throughout the enzyme, led to the enrichment of a set of protease variants that recognize and cleave the novel target substrate.

Dissecting the Structural Organization of Multiprotein Amyloid Aggregates Using a Bottom-Up Approach.

Deposition of fibrillar amyloid ß (Aß) in senile plaques is a pathological signature of Alzheimer's disease. However, senile plaques also contain many other components, including a range of different proteins. Although the composition of the plaques can be analyzed in post-mortem tissue, knowledge of the molecular details of these multiprotein inclusions and their assembly processes is limited, which impedes the progress in deciphering the biochemical mechanisms associated with Aß pathology. We describe here a bottom-up approach to monitor how proteins from human cerebrospinal fluid associate with Aß amyloid fibrils to form plaque particles. The method combines flow cytometry and mass spectrometry proteomics and allowed us to identify and quantify 128 components of the captured multiprotein aggregates. The results provide insights into the functional characteristics of the sequestered proteins and reveal distinct interactome responses for the two investigated Aß variants, Aß(1-40) and Aß(1-42). Furthermore, the quantitative data is used to build models of the structural organization of the multiprotein aggregates, which suggests that Aß is not the primary binding target for all the proteins; secondary interactions account for the majority of the assembled components. The study elucidates how different proteins are recruited into senile plaques and establishes a new model system for exploring the pathological mechanisms of Alzheimer's disease from a molecular perspective.

An Affibody Molecule Is Actively Transported into the Cerebrospinal Fluid via Binding to the Transferrin Receptor.

The use of biotherapeutics for the treatment of diseases of the central nervous system (CNS) is typically impeded by insufficient transport across the blood-brain barrier. Here, we investigate a strategy to potentially increase the uptake into the CNS of an affibody molecule (ZSYM73) via binding to the transferrin receptor (TfR). ZSYM73 binds monomeric amyloid beta, a peptide involved in Alzheimer's disease pathogenesis, with subnanomolar affinity. We generated a tri-specific fusion protein by genetically linking a single-chain variable fragment of the TfR-binding antibody 8D3 and an albumin-binding domain to the affibody molecule ZSYM73. Simultaneous tri-specific target engagement was confirmed in a biosensor experiment and the affinity for murine TfR was determined to 5 nM. Blockable binding to TfR on endothelial cells was demonstrated using flow cytometry and in a preclinical study we observed increased uptake of the tri-specific fusion protein into the cerebrospinal fluid 24 h after injection.

Directed evolution of the 3C protease from coxsackievirus using a novel fluorescence-assisted intracellular method.

Proteases are crucial for regulating biological processes in organisms through hydrolysis of peptide bonds. Recombinant proteases have moreover become important tools in biotechnological, and biomedical research and as therapeutics. We have developed a label-free high-throughput method for quantitative assessment of proteolytic activity in Escherichia coli. The screening method is based on co-expression of a protease of interest and a reporter complex. This reporter consists of an aggregation-prone peptide fused to a fluorescent protein via a linker that contains the corresponding substrate sequence. Cleavage of the substrate rescues the fluorescent protein from aggregation, resulting in increased fluorescence that correlates to proteolytic activity, which can be monitored using flow cytometry. In one round of flow-cytometric cell sorting, we isolated an efficiently cleaved tobacco etch virus (TEV) substrate from a 1:100 000 background of non-cleavable sequences, with around 6000-fold enrichment. We then engineered the 3C protease from coxsackievirus B3 (CVB3 3Cpro) towards improved proteolytic activity on the substrate LEVLFQ↓GP. We isolated highly proteolytic active variants from a randomly mutated CVB3 3Cpro library with up to 4-fold increase in activity. The method enables simultaneous measurement of proteolytic activity and protease expression levels and can therefore be applied for protease substrate profiling, as well as directed evolution of proteases.

Flow-cytometric screening of aggregation-inhibitors using a fluorescence-assisted intracellular method.

Aggregation of misfolded peptides and proteins is a key event in several neurodegenerative diseases. Suggested treatments of such disorders aim to inhibit the initial aggregation process. Here, we have developed an intracellular, function-based screening method, intended for isolation of aggregation-inhibitors from combinatorial protein libraries by flow-cytometric cell sorting. The method is based on fusion of aggregation-prone peptides to a fluorescent protein, functioning as a solubility reporter. Co-expression of a protein-based aggregation-inhibitor should prevent aggregation and thus increase the whole-cell fluorescence. We evaluated the method using the aggregation-prone Alzheimer's-related amyloid-ß (Aß) peptide in fusion to green-fluorescent protein (GFP), and an Aß aggregation-inhibiting Affibody molecule. To adapt the method for library applications, the inhibitor was linked to an mCherry reporter for normalization of protein expression levels. We found that aggregation propensity correlates with fluorescence intensity, as co-expression of the Affibody-inhibitor increased the whole-cell fluorescence relative to a non-inhibitor. Employing improved cultivation parameters, we furthermore demonstrated efficient rescue from aggregation of an α-synuclein-derived protein using a different type of aggregation-inhibitor. Importantly, we also showed that the Aß aggregation-inhibiting Affibody molecule could be isolated from a 1:10,000 background of non-inhibitors, with around 3,500-fold enrichment, in one cycle of fluorescence-based cell sorting. In conclusion, our new method represents a promising approach for generation of novel protein-based aggregation-inhibitors.