A new and simple method to tether a functional molecule at the proximity of the active site of an enzyme has been successfully developed without any activity loss. The one-pot sequential reaction was conducted on a surface of human carbonic anhydrase II (hCAII) based on the affinity labeling and the subsequent hydrazone/oxime exchange reaction. The reaction proceeds in a greater than 90% yield in the overall steps under mild conditions. The enzymatic activity assay demonstrated that the release of the affinity ligand from the active site of hCAII concurrently occurred with the replacement by the aminooxy derivatives, so that it restored the enzymatic activity from the completely suppressed state of the labeled hCAII. Such restoring of the activity upon the sequential modification is quite unique compared to conventional affinity labeling methods. The peptide mapping experiment revealed that the labeling reaction was selectively directed to His-3 or His-4, located on a protein surface proximal to the active site. When the fluorescent probe was tethered using the present sequential chemistry, the engineered hCAII can act as a fluorescent biosensor toward the hCAII inhibitors. This clearly indicates the two advantages of this method, that is (i) the modification is directed to the proximity of the active site and (ii) the sequential reaction re-opens the active site cavity of the target enzyme.
Antibiotic resistance is increasingly seen as a serious problem that threatens public health and erodes our capacity to effectively combat disease. So-called non-iron metalloporhyrins have shown promising antibacterial properties against a number of pathogenic bacteria including Staphylococcus aureus. However, little is known about the molecular mechanism(s) of action of these compounds and in particular how they reach the interior of the bacterial cells. A popular hypothesis indicates that non-iron metalloporphyrins infiltrate into bacterial cells like a "Trojan horse" using heme transport systems. Iron-regulated surface determinant (Isd) is the best characterized heme transport system of S. aureus. Herein we studied the molecular mechanism by which the extracellular heme-receptor IsdH-NEAT3 of Isd recognizes antimicrobial metalloporphyrins. We found that potent antibacterial porphyrins Ga(III)-protoporphyrin IX (PPIX) and Mn(III)-PPIX closely mimicked the properties of the natural ligand heme, namely (i) stable binding to IsdH-NEAT3 with comparable affinities for the receptor, (ii) nearly undistinghuishable three-dimensional structure when complexed with IsdH-NEAT3, and (iii) similar transfer properties to a second receptor IsdA. On the contrary, weaker antibacterial porphyrins Mg(II)-PPIX, Zn(II)-PPIX, and Cu(II)-PPIX were not captured effectively by IsdH-NEAT3 under our experimental conditions and displayed lower affinities. Moreover, reduction of Fe(III)-PPIX to Fe(II)-PPIX with dithionite abrogated stable binding to receptor. These data revealed a clear connection between oxidation state of metal and effective attachment to IsdH-NEAT3. Also, the strong correlation between binding affinity and reported antimicrobial potency suggested that the Isd system may be used by these antibacterial compounds to gain access to the interior of the cells. We hope these results will increase our understanding of Isd system of S. aureus and highlight its biomedical potential to deliver new and more efficient antibacterial treatments.
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