Chemokine binding to glycosaminoglycans (GAGs) is recognised to be an important step in inflammation and other pathological disorders like tumor growth and metastasis. Although different ways and strategies to interfere with these interactions are being pursued, no major breakthrough in the development of glycan-targeting drugs has been reported so far. We have engineered CXCL8 towards a dominant-negative form of this chemokine (dnCXCL8) which was shown to be highly active in various inflammatory animal models due to its inability to bind/activate the cognate CXCL8 GPC receptors on neutrophils in combination with its significantly increased GAG-binding affinity [1]. For the development of GAG-targeting chemokine-based biopharmaceuticals, we have established a repertoire of methods which allow the quantification of protein-GAG interactions. Isothermal fluorescence titration (IFT), surface plasmon resonance (SPR), isothermal titration calorimetry (ITC), and a novel ELISA-like competition assay (ELICO) have been used to determine K d and IC 50 values for CXCL8 and dnCXCL8 interacting with heparin and heparan sulfate (HS), the proto-typical members of the GAG family. Although the different methods gave different absolute affinities for the four protein-ligand pairs, the relative increase in GAG-binding affinity of dnCXCL8 compared to the wild type chemokine was found by all methods. In combination, these biophysical methods allow to discriminate between unspecific and specific protein-GAG interactions.
Hydroxynitrile lyases (HNLs) catalyze the cleavage of cyanohydrins. In the reverse reaction, they catalyze the formation of carbon-carbon bonds by enantioselective condensation of hydrocyanic acid with carbonyls. In this study, we describe two proteins from endophytic bacteria that display activity in the cleavage and the synthesis reaction of (R)-mandelonitrile with up to 74% conversion of benzaldehyde (enantiopreference ee 89%). Both showed high similarity to proteins of the cupin superfamily which so far were not known to exhibit HNL activity. Hydroxynitrile lyases (HNLs) catalyze the reversible cleavage of cyanohydrins, yielding the respective carbonyl compound and HCN. They are of great relevance in organic synthesis, in which the ability of the enzymes to catalyze the reverse reaction forming C-C bonds in a stereoselective manner is of substantial industrial relevance (9,11,19). Hydroxynitrile lyases are quite heterogeneous exhibiting remarkable diversity with respect to their substrate specificity, mass, glycosylation, and amino acid sequence, and their similarity to oxidoreductases, ␣/-hydrolases, carboxypeptidases, or Zn 2ϩ -containing alcohol dehydrogenases has been reported (3,4,8,17,18,19).Hydroxynitrile lyases are widespread in plants playing a major role in disease suppression, and only recently a bacterial protein with HNL activity in the cyanohydrin cleavage reaction was reported (16). Usually plants are colonized by a range of different bacteria (14). Endophytes in particular live in close association with their host and promote plant growth and health by various mechanisms, including the production of substances with phytohormonal activity or antimicrobial substances such as antibiotics (13,15,21). The production of HCN in pseudomonads has been reported (5), for example, but it has also been reported in other bacteria. In contrast to plants, cyanogenesis in bacteria usually follows a completely different biosynthetic pathway involving a HCN synthase (2,20). In this work, we present the discovery of a new bacterial enzyme class with hydroxynitrile lyase activity initially identified by function-based screening of a gene library of an isolated bacterial endophyte related to Pseudomonas mephitica and further investigated with a second highly similar protein from Burkholderia phytofirmans strain PsJN.Gene libraries of different endophytic bacteria isolated from potato were constructed in the pZero-2 vector by standard procedures (see supplemental material) and screened for HNL activity toward (R/S)-mandelonitrile using a colony-based colorimetric filter assay [67 mM (R/S)-mandelonitrile in 30 mM citratephosphate buffer (pH 3.5) at room temperature (RT)] (10). In the gene library of a strain related to Pseudomonas mephitica, HNL activity was detected. After subcloning and rescreening, the transformant exhibiting the strongest activity toward mandelonitrile was selected for further characterization. Sequencing revealed that the plasmid contained a 1,659-bp insert, which carried two open reading fram...
a b s t r a c tWe have engineered GPCR (G protein-coupled receptor) knock-out and high GAG-binding affinity into CXCL12a to inhibit CXCL12a-induced cell migration. Compared to wtCXCL12, the mutant CXCL12a (D8 L29K V39K) exhibited a 5.6-fold and a 2.2-fold affinity increase for heparin and heparan sulfate, respectively. From NaCl-based heparin displacement chromatography we concluded that more amino acid replacements would lead to altered GAG (glycosaminoglycan) ligand specificity. GAG silencing by this mutant was shown in a murine seeding model of human cancer cells, whereby a greatly reduced number of liver metastases was detected when the animals were treated intravenously with 1 mg/kg CXCL12a (D8 L29K V39K) before cancer cell application.
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