Hans-Lothar Fuchsbauer

Locked by Design: A Conformationally Constrained Transglutaminase Tag Enables Efficient Site-Specific Conjugation.

Based on the crystal structure of a natural protein substrate for microbial transglutaminase, an enzyme that catalyzes protein crosslinking, a recognition motif for site-specific conjugation was rationally designed. Conformationally locked by an intramolecular disulfide bond, this structural mimic of a native conjugation site ensured efficient conjugation of a reporter cargo to the therapeutic monoclonal antibody cetuximab without erosion of its binding properties.

Influence of Porcine Intervertebral Disc Matrix on Stem Cell Differentiation

For back disorders, cell therapy is one approach for a real regeneration of a degenerated nucleus pulposus. Human mesenchymal stem cells (hMSC) could be differentiated into nucleus pulposus (NP)-like cells and used for cell therapy. Therefore it is necessary to find a suitable biocompatible matrix, which supports differentiation. It could be shown that a differentiation of hMSC in a microbial transglutaminase cross-linked gelatin matrix is possible, but resulted in a more chondrocyte-like cell type. The addition of porcine NP extract to the gelatin matrix caused a differentiation closer to the desired NP cell phenotype. This concludes that a hydrogel containing NP extract without any other supplements could be suitable for differentiation of hMSCs into NP cells. The NP extract itself can be cross-linked by transglutaminase to build a hydrogel free of NP atypical substrates. As shown by side-specific biotinylation, the NP extract contains molecules with free glutamine and lysine residues available for the transglutaminase.

Structure of the Dispase Autolysis-inducing Protein from Streptomyces mobaraensis and Glutamine Cross-linking Sites for Transglutaminase.

Transglutaminase from Streptomyces mobaraensis (MTG) is an important enzyme for cross-linking and modifying proteins. An intrinsic substrate of MTG is the dispase autolysis-inducing protein (DAIP). The amino acid sequence of DAIP contains 5 potential glutamines and 10 lysines for MTG-mediated cross-linking. The aim of the study was to determine the structure and glutamine cross-linking sites of the first physiological MTG substrate. A production procedure was established in Escherichia coli BL21 (DE3) to obtain high yields of recombinant DAIP. DAIP variants were prepared by replacing four of five glutamines for asparagines in various combinations via site-directed mutagenesis. Incorporation of biotin cadaverine revealed a preference of MTG for the DAIP glutamines in the order of Gln-39 ≫ Gln-298 > Gln-345 ∼ Gln-65 ≫ Gln-144. In the structure of DAIP the preferred glutamines do cluster at the top of the seven-bladed β-propeller. This suggests a targeted cross-linking of DAIP by MTG that may occur after self-assembly in the bacterial cell wall. Based on our biochemical and structural data of the first physiological MTG substrate, we further provide novel insight into determinants of MTG-mediated modification, specificity, and efficiency.

The papain inhibitor (SPI) of Streptomyces mobaraensis inhibits bacterial cysteine proteases and is an antagonist of bacterial growth

ABSTRACT A novel papain inhibitory protein (SPI) from Streptomyces mobaraensis was studied to measure its inhibitory effect on bacterial cysteine protease activity (Staphylococcus aureus SspB) and culture supernatants (Porphyromonas gingivalis, Bacillus anthracis). Further, growth of Bacillus anthracis, Staphylococcus aureus, Pseudomonas aeruginosa, and Vibrio cholerae was completely inhibited by 10 μM SPI. At this concentration of SPI, no cytotoxicity was observed. We conclude that SPI inhibits bacterial virulence factors and has the potential to become a novel therapeutic treatment against a range of unrelated pathogenic bacteria.

Involvement of a Novel Class C Beta-Lactamase in the Transglutaminase Mediated Cross-Linking Cascade of Streptomyces mobaraensis DSM 40847

Streptomyces mobaraensis DSM 40847 secretes transglutaminase that cross-links proteins via γ-glutamyl-ε-lysine isopeptide bonds. Characterized substrates are inhibitory proteins acting against various serine, cysteine and metalloproteases. In the present study, the bacterial secretome was examined to uncover additional transglutaminase substrates. Fractional ethanol precipitation of the exported proteins at various times of culture growth, electrophoresis of the precipitated proteins, and sequencing of a 39 kDa protein by mass spectrometry revealed the novel beta-lactamase Sml-1. As indicated by biotinylated probes, Sml-1, produced in E. coli, exhibits glutamine and lysine residues accessible for transglutaminase. The chromogenic cephalosporin analogue, nitrocefin, was hydrolyzed by Sml-1 with low velocity. The obtained Km and kcat values of the recombinant enzyme were 94.3±1.8 μM and 0.39±0.03 s-1, respectively. Penicillin G and ampicillin proved to be weak inhibitors of nitrocefin hydrolysis (Ki of 0.1 mM and 0.18 mM). Negligible influence of metals on β-lactamase activity ruled out that Sml-1 is a Zn2+-dependent class B beta-lactamase. Rather, sequence motifs such as SITK, YSN, and HDG forming the active core in a hypothetical structure may be typical for class C beta-lactamases. Based on the results, we assume that the novel transglutaminase substrate ensures undisturbed growth of aerial hyphae in Streptomyces mobaraensis by trapping and inactivating hostile beta-lactam antibiotics.

Illuminating structure and acyl donor sites of a physiological transglutaminase substrate from Streptomyces mobaraensis : Transglutaminase Acyl Donor Interactions

Transglutaminase from Streptomyces mobaraensis (MTG) has become a powerful tool to covalently and highly specifically link functional amines to glutamine donor sites of therapeutic proteins. However, details regarding the mechanism of substrate recognition and interaction of the enzyme with proteinaceous substrates still remain mostly elusive. We have determined the crystal structure of the Streptomyces papain inhibitory protein (SPIp), a substrate of MTG, to study the influence of various substrate amino acids on positioning glutamine to the active site of MTG. SPIp exhibits a rigid, thermo‐resistant double‐psi‐beta‐barrel fold that is stabilized by two cysteine bridges. Incorporation of biotin cadaverine identified Gln‐6 as the only amine acceptor site on SPIp accessible for MTG. Substitution of Lys‐7 demonstrated that small and hydrophobic residues in close proximity to Gln‐6 favor MTG‐mediated modification and are likely to facilitate introduction of the substrate into the front vestibule of MTG. Moreover, exchange of various surface residues of SPIp for arginine and glutamate/aspartate outside the glutamine donor region influences the efficiency of modification by MTG. These results suggest the occurrence of charged contact areas between MTG and the acyl donor substrates beyond the front vestibule, and pave the way for protein engineering approaches to improve the properties of artificial MTG‐substrates used in biomedical applications.

Directed Evolution of a Bond-Forming Enzyme: Ultrahigh-Throughput Screening of Microbial Transglutaminase Using Yeast Surface Display

Microbial transglutaminase from Streptomyces mobaraensis (mTG) has emerged as a useful biotechnological tool due to its ability to crosslink a side chain of glutamine and primary amines. To date, the substrate specificity of mTG is not fully understood, which poses an obvious challenge when mTG is used to address novel targets. To that end, a viable strategy providing an access to tailor-made transglutaminases is required. This work reports an ultrahigh-throughput screening approach based on yeast surface display and fluorescence-activated cell sorting (FACS) that enabled the evolution of microbial transglutaminase towards enhanced activity. Five rounds of FACS screening followed by recombinant expression of the most potent variants in E. coli yielded variants that possessed, compared to the wild type enzyme, improved enzymatic performance and labeling behavior upon conjugation with an engineered therapeutic anti-HER2 antibody. This robust and generally applicable platform enables tailoring of the catalytic efficiency of mTG.

Features of the transglutaminase-activating metalloprotease from Streptomyces mobaraensis DSM 40847 produced in Escherichia coli.

Transglutaminase from Streptomyces mobaraensis (MTG) is an important enzyme for numerous industrial applications. Recombinant production requires proteolytic activation of the zymogen. The study provides a convenient procedure for the preparation of the transglutaminase-activating metalloprotease (TAMP) in Escherichia coli. In contrast to wtTAMP, rTAMP exhibited the P domain of convertases as molecular mass of 55.7u202fkDa suggested. Protein integrity was beneficially influenced by 2-5u202fmM CaCl2. Study of pH and temperature optima assigned rTAMP to the neutral metalloproteases, more heat-resistant than Dispase but not thermolysin. Zinc had no inhibiting effect but 3.1 μM EDTA completely reduced activity of 5u202fnM TAMP. MTG, exceeding concentration of rTAMP by three orders of magnitude, was largely activated within few minutes. The kinetic parameters KM (1.31u202f±u202f0.05u202fmM) and kcat (135u202f±u202f4.3 s-1), monitored by isothermal titration calorimetry (ITC), further highlighted catalytic efficiency (103,053 M-1 s-1) of rTAMP and rapid processing of MTG. ITC even revealed that inhibition of rTAMP by its intrinsic inhibitory protein SSTI was an enthalpy-driven process resulting in Kd of 199u202f±u202f37.9u202fnM. The production procedure of rTAMP in E. coli closes the gap between production and application of recombinant MTG and may enhance relevance of MTG-mediated reactions in pharmaceutical processes.

Destructive twisting of neutral metalloproteases: the catalysis mechanism of the Dispase autolysis-inducing protein from Streptomyces mobaraensis DSM 40487.

The Dispase autolysis‐inducing protein (DAIP) is produced by Streptomyces mobaraensis to disarm neutral metalloproteases by decomposition. The absence of a catalytic protease domain led to the assumption that the seven‐bladed β‐propeller protein DAIP causes structural modifications, thereby triggering autolysis. Determination of protein complexes consisting of DAIP and thermolysin or DAIP and a nonfunctional E138A bacillolysin variant supported this postulation. Protein twisting was indicated by DAIP‐mediated inhibition of thermolysin while bacillolysin underwent immediate autolysis under the same conditions. Interestingly, an increase in SYPRO orange fluorescence allowed tracking of the fast degradation process. Similarly rapid autolysis of thermolysin mediated by DAIP was only observed upon the addition of amphiphilic compounds, which probably amplify the induced structural changes. DAIP further caused degradation of FITC‐labeled E138A bacillolysin by trypsin, as monitored by a linear decrease in fluorescence polarization. The kinetic model, calculated from the obtained data, suggested a three‐step mechanism defined by (a) fast DAIP–metalloprotease complex formation, (b) slower DAIP‐mediated protein twisting, and (c) fragmentation. These results were substantiated by crystallized DAIP attached to a C‐terminal helix fragment of thermolysin. Structural superposition of the complex with thermolysin is indicative of a conformational change upon binding to DAIP. Importantly, the majority of metalloproteases, also including homologs from various pathogens, are highly conserved at the autolysis‐prone peptide bonds, suggesting their susceptibility to DAIP‐mediated decomposition, which may offer opportunities for pharmaceutical applications.

Identification of transglutaminase substrates from porcine nucleus pulposus as potential amplifiers in cross-linking cell scaffolds.

Nucleus pulposus from the porcine intervertebral disc was separated chromatographically to discover substrates of microbial transglutaminase. Highly purified proteins were prepared, among them type II collagen, the major protein of the nucleus pulposus. Determination of substrates was performed by transglutaminase-mediated incorporation of biotinylated probes displaying several glutamine and lysine donor proteins. Type II collagen was only labeled if smaller nucleus pulposus proteins were present. One of the modulating proteins was serotransferrin, a lysine donor substrate of bacterial transglutaminase. An additional substrate was the carboxy-terminal propeptide of type II collagen, chondrocalcin. Chondrocalcin, a regulator of type II collagen fibrillogenesis, occurs abundantly in juvenile cartilage and nucleus pulposus. Accordingly, the protein may be regarded as an excellent additive for the preparation of injectable stem cells in nucleus pulposus-like matrices cross-linked by microbial transglutaminase.