Comparative Assessment of the Structural Features of Originator Recombinant Human Follitropin Alfa Versus Recombinant Human Follitropin Alfa Biosimilar Preparations Approved in Non-European Regions.

Although the full primary structures of the alfa and beta subunits of reference r-hFSH-alfa and its biosimilars are identical, cell context-dependent differences in the expressing cell lines and manufacturing process can lead to variations in glycosylation profiles. In the present study, we compared the structural features of reference r-hFSH-alfa with those of five biosimilar preparations approved in different global regions outside Europe (Primapur®, Jin Sai Heng®, Follitrope®, Folisurge®, and Corneumon®) with respect to glycosylation, macro- and microheterogeneity, and other post-translational modifications and higher order structure. The mean proportion of N-glycosylation-site occupancy was highest in reference r-hFSH-alfa, decreasing sequentially in Primapur, Jin Sai Heng, Corneumon, Follisurge and Follitrope, respectively. The level of antennarity showed slightly higher complexity in Corneumon, Primapur and Follitrope versus reference r-hFSH-alfa, whereas Jin Sai Heng and Folisurge were aligned with reference r-hFSH-alfa across all N-glycosylation sites. Sialylation level was higher in Corneumon and Follitrope, but small differences were detected in other biosimilar preparations compared with reference r-hFSH-alfa. Jin Sai Heng showed higher levels of N-glyconeuramic acid than the other preparations. Minor differences in oxidation levels were seen among the different products. Therefore, in summary, we identified var ious differences in N-glycosylation occupancy, antennarity, sialylation and oxidation between reference r-hFSH-alfa and the biosimilar preparations analyzed.

Epitope Mapping and Binding Assessment by Solid-State NMR Provide a Way for the Development of Biologics under the Quality by Design Paradigm.

Multispecific biologics are an emerging class of drugs, in which antibodies and/or proteins designed to bind pharmacological targets are covalently linked or expressed as fusion proteins to increase both therapeutic efficacy and safety. Epitope mapping on the target proteins provides key information to improve the affinity and also to monitor the manufacturing process and drug stability. Solid-state NMR has been here used to identify the pattern of the residues of the programmed cell death ligand 1 (PD-L1) ectodomain that are involved in the interaction with a new multispecific biological drug. This is possible because the large size and the intrinsic flexibility of the complexes are not limiting factors for solid-state NMR.

Characterization of disulfide bridges pattern of recombinant human interleukin 12 fusion protein p40 subunit and identification and quantification of cysteinylated free cysteine 252.

RATIONALE: We show evidence of cysteinylation on Cys252 of recombinant human p40 subunit of interleukin 12 (IL-12). This was reported in 1996. However, no paper detailing this concept has been published yet. Our paper reports the quantification of Cys252 cysteinylation as well as the full disulfide bridges assignment by nonreducing peptide mapping using mass spectrometry (MS) detection. METHODS: Nonreducing peptide mapping was applied for disulfide bridges assignment. This study presents an ad hoc method in which applying a neutral pH in the presence of an alkylating agent allowed to mitigate the formation of artifacts such as reshuffled disulfide bridges and permitted the detection of free cysteine. Ultra-high-performance liquid chromatography-MS analysis was performed on a Waters quadrupole time-of-flight Xevo G2-XS mass spectrometer acquiring data in MSE mode. MS data were processed using Expressionist MS Refiner 13.5 (Genedata). RESULTS: Scouting experiments were performed using two batches of drug substance. An in-depth study of the LC tandem mass spectrometry profiles revealed the presence of additional species related to "free" Cys252; this cysteine residue was also detected in its S-cysteinylated and S-homocysteinylated forms. This result is consistent with that reported in literature so far. The relative abundance of overall "cysteinylated" species resulted in the range between 46% and 36%, which has also been confirmed using orthogonal techniques such as Ellman's assay. CONCLUSIONS: Our data clearly demonstrate that the free cysteine (Cys252) on the p40 subunit of recombinant IL-12 is also present in its cysteinylated and homocysteinylated forms at a considerable rate. Our observations, although based on results obtained on an IL-12-derived fusion protein, are consistent with the current literature.

Engineering a switch-based biosensor for arginine using a Thermotoga maritima periplasmic binding protein.

The Thermotoga maritima arginine-binding protein (TmArgBP) has been modified to create a reagentless fluorescent protein biosensor. Two design methods for biosensor construction are compared: 1) solvent accessibility of environmentally-sensitive probes and 2) fluorescence deactivation due to photo-induced electron transfer (PET). Nine single cysteine TmArgBP mutants were created and labeled with three different environmentally sensitive fluorescent probes. These mutants demonstrated limited changes in fluorescence emission upon the addition of arginine. In contrast, the PET-based biosensor provides significant enhancements over the traditional approach and provides a fluorescence quenching mechanism that was capable of providing quantitative detection of arginine. Site-directed mutagenesis of TmArgBP was used to create attachment points for the fluorescent probe (K145C) and for an internal aromatic residue (D18X) to serve as the PET quencher. Both tyrosine and tryptophan, but not phenylalanine, were able to quench the emission of the fluorescent probe by more than 80% upon the addition of arginine. The dissociation constant for arginine ranged from 0.87 to 1.5 µM across the different sensors. This PET-based strategy provides a simple and broadly applicable approach for the analytical detection of small molecules that may be applied to any protein that exhibits conformational switching in a ligand dependent manner.

Biological Functions of Interferon ß-1a Are Enhanced By Deamidation.

Human type I Interferons (IFN-ß, IFN-ɛ, IFN-κ, IFN-ω, and 12 subtypes of IFN-α) are a family of pleiotropic cytokines with antiviral, antiproliferative, and immunomodulatory activities. They signal through the same cell surface receptors, IFNAR1 and IFNAR2, yet evoking markedly differential potency. One differentiating factor of IFN-ß from other type I interferons is the presence of a consensus sequence (NG) for deamidation. Comparing almost completely deamidated IFN-ß-1a with untreated IFN-ß-1a, this present study reports the increased activities in 3 in-vitro bioassays testing the antiviral, antiproliferative, and immunomodulatory properties, respectively, of the molecule. Deamidated IFN-ß-1a has the potential to improve current therapies in multiple sclerosis, and its ability to potentiate the MHC-Class I expression suggests a clinical benefit in diseases where the downmodulation of the MHC-class I expression plays a role (eg, in immuno-oncology combination therapies or antiviral agents). The present study on IFN-ß deamidation adds a new prospective on deamidation as part of a posttranslational modification code that allows the modulation of the biological properties of proteins. Moreover, it underlines the unique IFN-ß-1a properties that differentiate this molecule from other members of the type I interferon family.

Tryptophan-scanning mutagenesis of the ligand binding pocket in Thermotoga maritima arginine-binding protein.

The Thermotoga maritima arginine binding protein (TmArgBP) is a member of the periplasmic binding protein superfamily. As a highly thermostable protein, TmArgBP has been investigated for the potential to serve as a protein scaffold for the development of fluorescent protein biosensors. To establish a relationship between structural dynamics and ligand binding capabilities, we constructed single tryptophan mutants to probe the arginine binding pocket. Trp residues placed around the binding pocket reveal a strong dependence on fluorescence emission of the protein with arginine for all but one of the mutants. Using these data, we calculated dissociation constants of 1.9-3.3 µM for arginine. Stern-Volmer quenching analysis demonstrated that the protein undergoes a large conformational change upon ligand binding, which is a common feature of this protein superfamily. While still active at room temperature, time-resolved intensity and anisotropy decay data suggest that the protein exists as a highly rigid structure under these conditions. Interestingly, TmArgBP exists as a dimer at room temperature in both the presence and absence of arginine, as determined by asymmetric flow field flow fractionation (AF4) and supported by native gel-electrophoresis and time-resolved anisotropy. Our data on dynamics and stability will contribute to our understanding of hyperthermophilic proteins and their potential biotechnological applications.

Crystallization and preliminary X-ray crystallographic analysis of ligand-free and arginine-bound forms of Thermotoga maritima arginine-binding protein.

The arginine-binding protein from Thermotoga maritima (TmArgBP) is an arginine-binding component of the ATP-binding cassette (ABC) transport system in this hyperthermophilic bacterium. This protein is endowed with an extraordinary stability towards thermal and chemical denaturation. Its structural characterization may provide useful insights for the clarification of structure-stability relationships and for the design of new biosensors. Crystallization trials were set up for both arginine-bound and ligand-free forms of TmArgBP and crystals suitable for crystallographic investigations were obtained for both forms. Ordered crystals of the arginine adduct of TmArgBP could only be obtained by using the detergent LDAO as an additive to the crystallization medium. These crystals were hexagonal, with unit-cell parameters a = 78.2, c = 434.7 Å, and diffracted to 2.7 Å resolution. The crystals of the ligand-free form were orthorhombic, with unit-cell parameters a = 51.8, b = 91.9, c = 117.9 Å, and diffracted to 2.25 Å resolution.

Amino acid transport in thermophiles: characterization of an arginine-binding protein in Thermotoga maritima. 2. Molecular organization and structural stability.

ABC transport systems provide selective passage of metabolites across cell membranes and typically require the presence of a soluble binding protein with high specificity to a specific ligand. In addition to their primary role in nutrient gathering, the binding proteins associated with bacterial transport systems have been studied for their potential to serve as design scaffolds for the development of fluorescent protein biosensors. In this work, we used Fourier transform infrared spectroscopy and molecular dynamics simulations to investigate the physicochemical properties of a hyperthermophilic binding protein from Thermotoga maritima. We demonstrated preferential binding for the polar amino acid arginine and experimentally monitored the significant stabilization achieved upon binding of ligand to protein. The effect of temperature, pH, and detergent was also studied to provide a more complete picture of the protein dynamics. A protein structure model was obtained and molecular dynamic experiments were performed to investigate and couple the spectroscopic observations with specific secondary structural elements. The data determined the presence of a buried beta-sheet providing significant stability to the protein under all conditions investigated. The specific amino acid residues responsible for arginine binding were also identified. Our data on dynamics and stability will contribute to our understanding of bacterial binding protein family members and their potential biotechnological applications.

Amino acid transport in thermophiles: characterization of an arginine-binding protein in Thermotoga maritima.

Members of the periplasmic binding protein superfamily are involved in the selective passage of ligands through bacterial cell membranes. The hyperthermophilic eubacterium Thermotoga maritima was found to encode a highly stable and specific periplasmic arginine-binding protein (TM0593). Following signal sequence removal and overexpression in Escherichia coli, TM0593 was purified by thermoprecipitation and affinity chromatography. The ultra-stable protein with a monomeric molecular weight of 27.7 kDa was found to exist as both a homodimer and homotrimer at appreciable concentrations even under strongly denaturing conditions, with an estimated transition temperature of 116 degrees C. Its multimeric structure may provide further evidence of the importance of quaternary structure in the movement of nutrients across bacterial membranes. Purified and refolded TM0593 was further characterized by fluorescence spectroscopy, mass spectrometry, and circular dichroism to demonstrate the specificity of the protein for arginine and to elucidate structural changes associated with arginine binding. The protein binds arginine with a dissociation constant of 20 muM as determined by surface plasmon resonance measurements. Due to its high thermodynamic stability, TM0593 may serve as a scaffold for the creation of a robust fluorescent biosensor.

FCS-based sensing for the detection of ochratoxin and neomycin in food.

In this work, we present an advanced fluorescence assay for the detection of traces of ocratoxin A and neomycin in food. The described assay is based on measurement of the fluctuations of the fluorescein-labeled analytes by a focused laser beam in the absence and in the presence of the specific antibodies anti-analytes. A competitive assay based on the utilization of unlabeled analytes was developed. The obtained results indicated that the combination of high-avidity IgG antibodies together with an innovative fluorescence immunoassay strategy resulted in the detection limit of 0.0078 ng and 0.0156 ng for ochratoxin A and neomycin, respectively.

Nanostructured silver-based surfaces: new emergent methodologies for an easy detection of analytes.

In this work, we describe how to realize a new sensing platform for an easy and fast detection of analytes. In particular, we utilized enhanced fluorescence emission on silver island films (SIFs) coupled to the total internal reflection fluorescence mode (TIRF) to develop a new assay format for the detection of target analytes. Here, as an example, we report on the detection of the toxic peptides present in gliadin (Gli). Our assay was performed as follows: (1) gliadin was first captured on surfaces coated with anti-Gli antibodies; (2) the surfaces were then incubated with fluorophore-labeled anti-Gli antibodies; (3) the signal from the fluorophore-labeled anti-Gli antibody bound to the antigen was detected by TIRF. The system was examined on glass surfaces and on SIFs. We observed a relevant enhancement of the signal from SIFs compared to the signal from the glass substrate not modified with a SIF. In addition, the estimated detection limit (EDL) of our methodology was 60 ng/mL (or lower). This limit is therefore lower than the clinical cut-off for Gli presence in food for celiac patients. The advantage of our method is a reduced number of testing steps, which allows for easy detection of residual toxic peptides in food labeled as gluten free. The proposed technology can be easily expanded to the determination of different target analytes.

Molecular strategies for protein stabilization: the case of a trehalose/maltose-binding protein from Thermus thermophilus.

The trehalose/maltose-binding protein (MalE1) is one component of trehalose and maltose uptake system in the thermophilic organism Thermus thermophilus. MalE1 is a monomeric 48 kDa protein predominantly organized in alpha-helix conformation with a minor content of beta-structure. In this work, we used Fourier-infrared spectroscopy and in silico methodologies for investigating the structural stability properties of MalE1. The protein was studied in the absence and in the presence of maltose as well as in the absence and in the presence of SDS at different p(2)H values (neutral p(2)H and at p(2)H 9.8). In the absence of SDS, the results pointed out a high thermostability of the MalE1 alpha-helices, maintained also at basic p(2)H values. However, the obtained data also showed that at high temperatures the MalE1 beta-sheets underwent to structural rearrangements that were totally reversible when the temperature was lowered. At room temperature, the addition of SDS to the protein solution slightly modified the MalE1 secondary structure content by decreasing the protein thermostability. The infrared data, corroborated by molecular dynamics simulation experiments performed on the structure of MalE1, indicated that the protein hydrophobic interactions have an important role in the MalE1 high thermostability. Finally, the results obtained on MalE1 are also discussed in comparison with the data on similar thermostable proteins already studied in our laboratories.

D-galactose/D-glucose-binding Protein from Escherichia coli as Probe for a Non-consuming Glucose Implantable Fluorescence Biosensor.

D-Galactose/D-glucose-binding protein from E. coli (GGBP) is a monomer thatbinds glucose with high affinity. The protein structure of GGBP is organized in twoprincipal domains linked by a hinge region that form the sugar-binding site. In this workwe show that the mutant form of GGBP at the amino acid position 182 can be utilized as aprobe for the development of a non-consuming analyte fluorescence biosensor to monitorthe glucose level in diabetes health care.