Complement-regulatory biomaterial coatings: Activity and selectivity profile of the factor H-binding peptide 5C6.

The use of biomaterials in modern medicine has enabled advanced drug delivery strategies and led to reduced morbidity and mortality in a variety of interventions such as transplantation or hemodialysis. However, immune-mediated reactions still present a serious complication of these applications. One of the drivers of such reactions is the complement system, a central part of humoral innate immunity that acts as a first-in-line defense system in its own right but also coordinates other host defense responses. A major regulator of the complement system is the abundant plasma protein factor H (FH), which impairs the amplification of complement responses. Previously, we could show that it is possible to recruit FH to biomedical surfaces using the phage display-derived cyclic peptide 5C6 and, consequently, reduce deposition of C3b, an activation product of the complement system. However, the optimal orientation of 5C6 on surfaces, structural determinants within the peptide for the binding, and the exact binding region on FH remained unknown. Here, we show that the cyclic core and C-terminal region of 5C6 are essential for its interaction with FH and that coating through its N-terminus strongly increases FH recruitment and reduces C3-mediated opsonization in a microparticle-based assay. Furthermore, we could demonstrate that 5C6 selectively binds to FH but not to related proteins. The observation that 5C6 also binds murine FH raises the potential for translational evaluation in animal models. This work provides important insight for the future development of 5C6 as a probe or therapeutic entity to reduce complement activation on biomaterials. STATEMENT OF SIGNIFICANCE: Biomaterials have evolved into core technologies critical to biomedical and drug delivery applications alike, yet their safe and efficient use may be adversely impacted by immune responses to the foreign materials. Taking inspiration from microbial immune evasion strategies, our group developed a peptide-based surface coating that recruits factor H (FH), a host regulator of the complement system, from plasma to the material surface and prevents unwanted activation of this innate immunity pathway. In this study, we identified the molecular determinants that define the interaction between FH and the coated peptide, developed tethering strategies with largely enhanced binding capacity and provided important insight into the target selectivity and species specificity of the FH-binding peptide, thereby paving the way for preclinical development steps.

Expression of the carbohydrate recognition domain of FimH and development of a competitive binding assay.

Uropathogenic Escherichia coli (UPEC) is the primary cause of urinary tract infections (UTIs). In the first step of this infective process, the virulence factor FimH located on type 1 pili allows UPEC to specifically adhere to oligosaccharides, which are part of glycoproteins on the urinary bladder mucosa. This initial step prevents the clearance of E. coli from the urinary tract and enables the invasion of the host cells. Because FimH antagonists can block this interaction, they exhibit a promising therapeutic potential as anti-infectives. For the evaluation of their binding properties, a reliable, target-based affinity assay is required. Here, we describe the expression and purification of the carbohydrate recognition domain of FimH (FimH-CRD) as well as the development of a competitive binding assay. FimH-CRD linked with a thrombin cleavage site to a 6His-tag is recombinantly expressed and purified by affinity chromatography. For the evaluation of FimH antagonists, a cell-free binding assay based on the interaction of a biotinylated polyacrylamide glycopolymer with the FimH-CRD was developed. Complexation of the biotinylated glycopolymer with streptavidin coupled to horseradish peroxidase allows the quantification of the binding properties of FimH antagonists. The assay format was optimized and validated by a comparison with affinity data from reported assays.

A novel approach to intraoral mandibular nerve anesthesia: changing reference planes in the Gow-Gates block technique.

PURPOSE: The Gow-Gates technique is said to have several advantages over traditional techniques to achieve mandibular nerve anesthesia; however, its routine use is quite limited, mainly due to complications during visual alignment of reference landmarks. The purpose of this study was to verify the validity and accuracy of a new method to reach the injection site. MATERIAL AND METHODS: Fifteen magnetic resonance images were captured. Distances from the ideal injection point in the condylar neck (puncture ideal) to the injection points located in the alpha and beta plane intersection (puncture Gow-Gates and puncture modified) were measured and compared. RESULTS: Positive and significant (P

Urinary Tract Infection: Which Conformation of the Bacterial Lectin FimH Is Therapeutically Relevant?

Frequent antibiotic treatment of urinary tract infections has resulted in the emergence of antimicrobial resistance, necessitating alternative treatment options. One such approach centers around FimH antagonists that block the bacterial adhesin FimH, which would otherwise mediate binding of uropathogenic Escherichia coli to the host urothelium to trigger the infection. Although the FimH lectin can adopt three distinct conformations, the evaluation of FimH antagonists has mainly been performed with a truncated construct of FimH locked in one particular conformation. For a successful therapeutic application, however, FimH antagonists should be efficacious against all physiologically relevant conformations. Therefore, FimH constructs with the capacity to adopt various conformations were applied. By examining the binding properties of a series of FimH antagonists in terms of binding affinity and thermodynamics, we demonstrate that depending on the FimH construct, affinities may be overestimated by a constant factor of 2 orders of magnitude. In addition, we report several antagonists with excellent affinities for all FimH conformations.