Carbonic anhydrases (CAs, EC 4.2.1.1) are a family of metalloenzymes that catalyze the reversible interconversion of CO(2) and HCO(3)(-). Of the 15 isoforms of human (h) α-CA, 12 are catalytic (hCAs I-IV, VA, VB, VI, VII, IX, XII-XIV). The remaining three acatalytic isoforms (hCAs VIII, X and XI) lack the active site Zn(2+) and are referred to as CA-related proteins (CA-RPs); however, their function remains elusive. Overall these isoforms are very similar to each other in structure but they differ in their expression and distribution. The favourable properties of hCA II such as fast kinetics, easy expression and purification, high solubility and intermediate heat resistance have made it an attractive candidate for numerous industrial applications. This review highlights the structural similarity and stability comparison among hCAs.
Carbonic anhydrases (CAs, EC 4.2.1.1) are a group of metalloenzymes that play important roles in carbon metabolism, pH regulation, CO2 fixation in plants, ion transport etc., and are found in all eukaryotic and many microbial organisms. This family of enzymes catalyzes the interconversion of CO2 and HCO3−. There are at least 16 different CA isoforms in the alpha structural class (α-CAs) that have been isolated in higher vertebrates, with CA isoform II (CA II) being ubiquitously abundant in all human cell types. CA inhibition has been exploited clinically for decades for various classes of diuretics and anti-glaucoma treatment. The characterization of the overexpression of CA isoform IX (CA IX) in certain tumors has raised interest in CA IX as a diagnostic marker and drug target for aggressive cancers and therefore the development of CA IX specific inhibitors. An important goal in the field of CA is to identify, rationalize, and design potential compounds that will preferentially inhibit CA IX over all other isoforms of CA. The variations in the active sites between isoforms of CA are subtle and this causes non-specific CA inhibition which leads to various side effects. In the case of CA IX inhibition, CA II along with other isoforms of CA provide off-target binding sites which is undesirable for cancer treatment. The focus of this article is on CA IX inhibition and two different structural approaches to CA isoform specific drug designing: tail approach and fragment addition approach.
Based on the observed active-site binding interactions of CAIs in crystal structures and their respective inhibition constants, structure-activity relationships can be mapped. Various CAIs along with novel techniques to administer them have been patented in the last four years. However, epilepsy continues to be a path less traveled when it comes to CAIs. A major area of research must focus toward the design of isoform-specific inhibitors using analogs of existing CAIs.
Human carbonic anhydrases are zinc metalloenzymes that catalyze the hydration and dehydration of CO2 and HCO3
−, respectively. X-ray crystal structures of a variant of human carbonic anhydrase II in complex with four imidazole derivatives (imidazole, 1-methylimidazole, 2-methylimidazole and 4-methylimidazole) have been determined in order to identify the binding sites for such compounds, and a mechanism to explain the effects on catalytic activity is proposed.
Protein X-ray crystallography has seen a progressive shift from data collection at cool/room temperature (277-298 K) to data collection at cryotemperature (100 K) because of its ease of crystal preparation and the lessening of the detrimental effects of radiation-induced crystal damage, with 20-25%(v/v) glycerol (GOL) being the preferred choice of cryoprotectant. Here, a case study of the effects of cryoprotectants on the kinetics of carbonic anhydrase II (CA II) and its inhibition by the clinically used inhibitor acetazolamide (AZM) is presented. Comparative studies of crystal structure, kinetics, inhibition and thermostability were performed on CA II and its complex with AZM in the presence of either GOL or sucrose. These results suggest that even though the cryoprotectant GOL was previously shown to be directly bound in the active site and to interact with AZM, it affects neither the thermostability of CA II nor the binding of AZM in the crystal structure or in solution. However, addition of GOL does affect the kinetics of CA II, presumably as it displaces the water proton-transfer network in the active site.
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