Biocatalytic Method for Producing an Affinity Resin for the Isolation of Immunoglobulins.

Affinity chromatography is a widely used technique for antibody isolation. This article presents the successful synthesis of a novel affinity resin with a mutant form of protein A (BsrtA) immobilized on it as a ligand. The key aspect of the described process is the biocatalytic immobilization of the ligand onto the matrix using the sortase A enzyme. Moreover, we used a matrix with primary amino groups without modification, which greatly simplifies the synthesis process. The resulting resin shows a high dynamic binding capacity (up to 50 mg IgG per 1 mL of sorbent). It also demonstrates high tolerance to 0.1 M NaOH treatment and maintains its effectiveness even after 100 binding, elution, and sanitization cycles.

A trimetal site and substrate distortion in a family II inorganic pyrophosphatase.

We report the first crystal structures of a family II pyrophosphatase complexed with a substrate analogue, imidodiphosphate (PNP). These provide new insights into the catalytic reaction mechanism of this enzyme family. We were able to capture the substrate complex both by fluoride inhibition and by site-directed mutagenesis providing complementary snapshots of the Michaelis complex. Structures of both the fluoride-inhibited wild type and the H98Q variant of the PNP-Bacillus subtilis pyrophosphatase complex show a unique trinuclear metal center. Each metal ion coordinates a terminal oxygen on the electrophilic phosphate and a lone pair on the putative nucleophile, thus placing it in line with the scissile bond without any coordination by protein. The nucleophile moves further away from the electrophilic phosphorus site, to the opposite side of the trimetal plane, upon binding of substrate. In comparison with earlier product complexes, the side chain of Lys296 has swung in and so three positively charged side chains, His98, Lys205 and Lys296, now surround the bridging nitrogen in PNP. Finally, one of the active sites in the wild-type structure appears to show evidence of substrate distortion. Binding to the enzyme may thus strain the substrate and thus enhance the catalytic rate.

ATP hydrolysis and AMP kinase activities of nonstructural protein 2C of human parechovirus 1.

The highly conserved picornavirus 2C proteins, thought to be involved in genome replication, contain three motifs found in NTPases/helicases of superfamily III. We report that human parechovirus 1 2C displays Mg2+-dependent ATP diphosphohydrolase activity in vitro, whereas other nucleoside triphosphates are not substrates for the hydrolysis. We also found that the 2C protein has an enzymatic activity that converts AMP to a corresponding diphosphate using ADP or ATP as a phosphate donor. In addition, we observed that ATP hydrolysis results in 2C autophosphorylation. These findings indicate that the parechovirus 2C protein has enzymatic activities, which may contribute to several functions in the viral replication cycle.

Unusual twinning in an acetyl coenzyme A synthetase (ADP-forming) from Pyrococcus furiosus.

A recombinant form of an acetyl coenzyme A synthetase (ADP-forming) from Pyrococcus furiosus has been crystallized. Crystallization was accomplished by the sitting-drop vapour-diffusion technique. Crystals belong to the monoclinic space group C2, with unit-cell parameters a = 131.3, b = 186.1, c = 121.5 angstroms, beta = 122.6 degrees, and diffract to 2.0 angstroms resolution on a synchrotron-radiation source. The unit-cell parameters allow twinning to the higher apparent space-group symmetry F222 by twin-lattice quasi-symmetry. The twinning fraction for the data is close to 40%. Two other data sets in the PDB show similar twinning.

Site-specific effects of zinc on the activity of family II pyrophosphatase.

Family II pyrophosphatases (PPases), recently found in bacteria and archaebacteria, are Mn(2+)-containing metalloenzymes with two metal-binding subsites (M1 and M2) in the active site. These PPases can use a number of other divalent metal ions as the cofactor but are inactive with Zn(2+), which is known to be a good cofactor for family I PPases. We report here that the Mg(2+)-bound form of the family II PPase from Streptococcus gordonii is nearly instantly activated by incubation with equimolar Zn(2+), but the activity thereafter decays on a time scale of minutes. The activation of the Mn(2+)-form by Zn(2+) was slower but persisted for hours, whereas activation was not observed with the Ca(2+)- and apo-forms. The bound Zn(2+) could be removed from PPase by prolonged EDTA treatment, with a complete recovery of activity. On the basis of the effect of Zn(2+) on PPase dimerization, the Zn(2+) binding constant appeared to be as low as 10(-12) M for S. gordonii PPase. Similar effects of Zn(2+) and EDTA were observed with the Mg(2+)- and apo-forms of Streptococcus mutans and Bacillus subtilis PPases. The effects of Zn(2+) on the apo- and Mg(2+)-forms of HQ97 and DE15 B. subtilis PPase variants (modified M2 subsite) but not of HQ9 variant (modified M1 subsite) were similar to that for the Mn(2+)-form of wild-type PPase. These findings can be explained by assuming that (a) the PPase tightly binds Mg(2+) and Mn(2+) at the M2 subsite; (b) the activation of the corresponding holoenzymes by Zn(2+) results from its binding to the M1 subsite; and (c) the subsequent inactivation of Mg(2+)-PPase results from Zn(2+) migration to the M2 subsite. The inability of Zn(2+) to activate apo-PPase suggests that Zn(2+) binds more tightly to M2 than to M1, allowing direct binding to M2. Zn(2+) is thus an efficient cofactor at subsite M1 but not at subsite M2.

Structural studies of metal ions in family II pyrophosphatases: the requirement for a Janus ion.

Family II inorganic pyrophosphatases (PPases) constitute a new evolutionary group of PPases, with a different fold and mechanism than the common family I enzyme; they are related to the "DHH" family of phosphoesterases. Biochemical studies have shown that Mn(2+) and Co(2+) preferentially activate family II PPases; Mg(2+) partially activates; and Zn(2+) can either activate or inhibit (Zyryanov et al., Biochemistry, 43, 14395-14402, accompanying paper in this issue). The three solved family II PPase structures did not explain the differences between the PPase families nor the metal ion differences described above. We therefore solved three new family II PPase structures: Bacillus subtilis PPase (Bs-PPase) dimer core bound to Mn(2+) at 1.3 A resolution, and, at 2.05 A resolution, metal-free Bs-PPase and Streptococcus gordonii (Sg-PPase) containing sulfate and Zn(2+). Comparison of the new and old structures of various family II PPases demonstrates why the family II enzyme prefers Mn(2+) or Co(2+), as an activator rather than Mg(2+). Both M1 and M2 undergo significant changes upon substrate binding, changing from five-coordinate to octahedral geometry. Mn(2+) and Co(2+), which readily adopt different coordination states and geometries, are thus favored. Combining our structures with biochemical data, we identified M2 as the high-affinity metal site. Zn(2+) activates in the M1 site, where octahedral geometry is not essential for catalysis, but inhibits in the M2 site, because it is unable to assume octahedral geometry but remains trigonal bipyramidal. Finally, we propose that Lys205-Gln81-Gln80 form a hydrophilic channel to speed product release from the active site.