Discovery of a microbial transglutaminase enabling highly site-specific labeling of proteins.

Microbial transglutaminases (MTGs) catalyze the formation of Gln-Lys isopeptide bonds and are widely used for the cross-linking of proteins and peptides in food and biotechnological applications (e.g. to improve the texture of protein-rich foods or in generating antibody-drug conjugates). Currently used MTGs have low substrate specificity, impeding their biotechnological use as enzymes that do not cross-react with nontarget substrates (i.e. as bio-orthogonal labeling systems). Here, we report the discovery of an MTG from Kutzneria albida (KalbTG), which exhibited no cross-reactivity with known MTG substrates or commonly used target proteins, such as antibodies. KalbTG was produced in Escherichia coli as soluble and active enzyme in the presence of its natural inhibitor ammonium to prevent potentially toxic cross-linking activity. The crystal structure of KalbTG revealed a conserved core similar to other MTGs but very short surface loops, making it the smallest MTG characterized to date. Ultra-dense peptide array technology involving a pool of 1.4 million unique peptides identified specific recognition motifs for KalbTG in these peptides. We determined that the motifs YRYRQ and RYESK are the best Gln and Lys substrates of KalbTG, respectively. By first reacting a bifunctionalized peptide with the more specific KalbTG and in a second step with the less specific MTG from Streptomyces mobaraensis, a successful bio-orthogonal labeling system was demonstrated. Fusing the KalbTG recognition motif to an antibody allowed for site-specific and ratio-controlled labeling using low label excess. Its site specificity, favorable kinetics, ease of use, and cost-effective production render KalbTG an attractive tool for a broad range of applications, including production of therapeutic antibody-drug conjugates.

Prevention of hepatitis C virus infection and spread in human liver chimeric mice by an anti-CD81 monoclonal antibody.

UNLABELLED: CD81 is a required receptor for hepatitis C virus (HCV) infection of human hepatocytes in vitro. We generated several high-affinity anti-human CD81 monoclonal antibodies (mAbs) that demonstrated potent, specific, and cross-genotype inhibition of HCV entry. One of these mAbs, K04, was administered to human liver chimeric mice before or after HCV infection to determine its ability to prevent HCV infection or spread of HCV infection, respectively. All vehicle control mice established HCV infection, reaching steady-state levels of serum HCV RNA by day 21. Pretreatment of mice with K04 prevented HCV infection in all mice (n = 5). Treatment of mice with mAb K04 every 3 days for 21 days, starting at 6 hours postinfection, resulted in effective inhibition of virus spread. In 3 mice that were sacrificed on day 24, serum HCV levels remained detectable, below the limit of quantification (LOQ), indicating that infection was established, but virus spread was blocked, by the anti-CD81 mAb. In 5 additional mice that were followed for a longer time, virus remained detectable, below LOQ, until days 24 and 30 in 4 of 5 mice. In the fifth mouse, viral load was quantifiable, but reduced to 64-fold below the mean viral load in vehicle control at day 24. In addition, 2 of 5 mice cleared the infection by day 30 and 1 mouse had undetectable virus load from day 6 onward. CONCLUSION: These results demonstrate that CD81 is required for HCV infection and virus spread in vivo, and that anti-CD81 antibodies such as K04 may have potential as broad-spectrum antiviral agents for prevention and treatment of HCV infection.

Development of a first-in-class antibody and a specific assay for α-1,6-fucosylated prostate-specific antigen.

Prostate-specific antigen (PSA) levels are widely used to screen for prostate cancer, yet the test has poor sensitivity, specificity and predictive value, which leads to overdiagnosis and overtreatment. Alterations in the glycosylation status of PSA, including fucosylation, may offer scope for an improved biomarker. We sought to generate a monoclonal antibody (mAb) targeting α-1,6-fucosylated PSA (fuc-PSA) and to develop a tissue-based immunological assay for fuc-PSA detection. Immunogens representing fuc-PSA were used for immunisation and resultant mAbs were extensively characterised. The mAbs reacted specifically with fuc-PSA-specific glycopeptide, but not with aglycosylated PSA or glycan without the PSA peptide. Reactivity was confirmed using high-throughput surface plasmon resonance spectroscopy. X-ray crystallography investigations showed that the mAbs bound to an α-helical form of the peptide, whereas the native PSA epitope is linear. Protein unfolding was required for detection of fuc-PSA in patient samples. Peptide inhibition of fuc-PSA mAbs was observed with positive screening reagents, and target epitope specificity was observed in formalin-fixed, paraffin-embedded tissue samples. This research introduces a well-characterised, first-in-class antibody targeting fuc-PSA and presents the first crystal structure of an antibody demonstrating glycosylation-specific binding to a peptide.

Transient gene expression using valproic acid in combination with co-transfection of SV40 large T antigen and human p21CIP /p27KIP.

Transient gene expression (TGE) in HEK293 cells was optimized by Vink et al. by co-expression of human cell cycle inhibitors p21CIP /p27KIP and Simian virus 40 large T antigen (SVLT). In this study, we investigated the effect of this enhancer protein complex on the TGE experiments in a cell-cycle arrested condition of HEK293F cells induced by valproic acid. Growth profiles, consumptions of nutrients, formations of waste products, and product titers of recombinant human antibodies (huAb) were monitored during the 7-day cultivation time. Our results showed that the use of enhancer proteins increased the product yields in a growth arrest condition as well. During the growth phase, no differences were detected regarding viable cell densities (VCDs), viabilities, growth rates, and cell diameters between the TGE experiments with and without enhancer proteins. However, during the declining phase VCD and viability showed slightly higher values at day 6 and 7 in the presence of enhancers. Furthermore, we could not detect any differences in glucose and glutamine metabolism during batch cultivations with co-expression of enhancer proteins. Taken together, the special complex of enhancer proteins did not contribute to further enhancement of growth arrest and shift in the main cell metabolisms, but resulted in higher cell viability during the decline phase. Our observations suggest that the human cell cycle inhibitors p21CIP /p27KIP together with very low amount of SVLT antigen may induce alternative functional activities than growth arrest to further improve the yield of recombinant proteins.

Development of bispecific molecules for the in situ detection of protein-protein interactions and protein phosphorylation.

Investigation of protein-protein interactions (PPIs) and protein phosphorylation in clinical tissue samples can offer valuable information about the activation status and function of proteins involved in disease progression. However, existing antibody-based methods for phosphorylation detection have been found to lack specificity, and methods developed for examining PPIs in vitro cannot be easily adapted for tissues samples. In this study, we eliminated some of these limitations by developing a specific immunohistochemical staining method that uses "dual binders" (DBs), which are bispecific detection agents consisting of two Fab fragment molecules joined by a flexible linker, to detect PPIs and protein phosphorylation. We engineered DBs by selecting Fab fragments with fast off-rate kinetics, which allowed us to demonstrate that stable target binding was achieved only upon simultaneous, cooperative binding to both epitopes. We show that DBs specifically detect the activated HER2/HER3 complex in formalin-fixed, paraffin-embedded cancer cells and exhibit superior detection specificity for phospho-HER3 compared to the corresponding monoclonal antibody. Overall, the performance of DBs makes them attractive tools for future development for clinical applications.

Crystal structure of human TWEAK in complex with the Fab fragment of a neutralizing antibody reveals insights into receptor binding.

The tumor necrosis factor-like weak inducer of apoptosis (TWEAK) is a multifunctional cytokine playing a key role in tissue regeneration and remodeling. Dysregulation of TWEAK signaling is involved in various pathological processes like autoimmune diseases and cancer. The unique interaction with its cognate receptor Fn14 makes both ligand and receptor promising targets for novel therapeutics. To gain insights into this important signaling pathway, we determined the structure of soluble human TWEAK in complex with the Fab fragment of an antibody selected for inhibition of receptor binding. In the crystallized complex TWEAK is bound by three Fab fragments of the neutralizing antibody. Homology modeling shows that Fab binding overlaps with the putative Fn14 binding site of TWEAK. Docking of the Fn14 cysteine rich domain (CRD) to that site generates a highly complementary interface with perfectly opposing charged and hydrophobic residues. Taken together the presented structure provides new insights into the biology of TWEAK and the TWEAK/Fn14 pathway, which will help to optimize the therapeutic strategy for treatment of related cancer types and autoimmune diseases.

Target-mediated drug disposition and prolonged liver accumulation of a novel humanized anti-CD81 monoclonal antibody in cynomolgus monkeys.

CD81 is an essential receptor for hepatitis C virus (HCV). K21 is a novel high affinity anti-CD81 antibody with potent broad spectrum anti-HCV activity in vitro. The pharmacokinetics (PK), pharmacodynamics and liver distribution of K21 were characterized in cynomolgus monkeys after intravenous (i.v.) administration of K21. Characteristic target-mediated drug disposition (TMDD) was shown based on the PK profile of K21 and a semi-mechanistic TMDD model was used to analyze the data. From the TMDD model, the estimated size of the total target pool at baseline (V(c) • R(base)) is 16 nmol/kg and the estimated apparent Michaelis-Menten constant (KM) is 4.01 nM. A simulation using estimated TMDD parameters indicated that the number of free receptors remains below 1% for at least 3 h after an i.v. bolus of 7 mg/kg. Experimentally, the availability of free CD81 on peripheral lymphocytes was measured by immunostaining with anti-CD81 antibody JS81. After K21 administration, a dose- and time-dependent reduction in free CD81 on peripheral lymphocytes was observed. Fewer than 3% of B cells could bind JS81 3 h after a 7 mg/kg dose. High concentrations of K21 were found in liver homogenates, and the liver/serum ratio of K21 increased time-dependently and reached ~160 at 168 h post-administration. The presence of K21 bound to hepatocytes was confirmed by immunohistochemistry. The fast serum clearance of K21 and accumulation in the liver are consistent with TMDD. The TMDD-driven liver accumulation of the anti-CD81 antibody K21 supports the further investigation of K21 as a therapeutic inhibitor of HCV entry.