Site directed mutagenesis as a tool to understand the catalytic mechanism of human cytidine deaminase.

Cytidine deaminase (CDA), is one of the enzymes involved in the pyrimidine salvage pathways, which catalyzes the formation of uridine and deoxyuridine by the hydrolytic deamination of cytidine and deoxycytidine, respectively. Human CDA is a tetrameric enzyme of identical 15 kDa subunits, each containing an essential zinc atom in the active site. The substrate binds to each active site independently and the cooperativity between subunits has not been reported. CDA is able to recognize as substrates some antitumor and antiviral cytidine analogs rendering them pharmacologically inactive. In light of the role played by this enzyme, a deep knowledge of CDA active site and mechanism of catalysis is required. Site-directed mutagenesis, associated with molecular modeling studies, may be an important tool to discover the active site structure of an enzyme and consequently its mechanism of action. In this review are summarized the site-directed mutagenesis experiments performed on human CDA: through these studies it was possible to understand the role exerted by specific amino acid residues in CDA active site and in the contacts between subunits. The obtained results may open a way for designing new cytidine based drugs or more potent CDA inhibitors.

Rapid allele-specific PCR method for CDA 79A>C (K27Q) genotyping: a useful pharmacogenetic tool and world-wide polymorphism distribution.

BACKGROUND: The CDA 79A>C (K27Q, rs2072671) functional SNP has recently shown a crucial role in the pharmacogenetics of cytidine-based anticancer drugs widely administered to different subsets of patients. Current gold standard in screening for the CDA rs2072671 is the sequence-based genotyping method. Here we developed a novel, rapid Allele-Specific PCR method for CDA rs2072671 genotyping. METHODS: DNA was extracted from 324 healthy individuals from two different populations (Italian and Han Chinese). CDA rs2072671 genotyping was performed by Allele-Specific PCR. Sequencing was performed to validate the test results. Results obtained from population screening were compared to that already available in HapMap and in the literature. RESULTS: Samples analyzed were successfully genotyped and the results were confirmed by sequencing. Genotype distribution does not differ significantly from that previously reported for each relative ethnic group. Also, the world-wide distribution of the CDA rs2072671 SNP is reported. A striking difference is present among the main ethnicities (p=1.715×10(-77)), with CDA*27Q allele showing the lowest frequency in African group (9.7%) and the highest in Caucasians (35.9%). CONCLUSION: This Allele-Specific PCR method is a useful tool in pharmacogenetics research and a valid and reliable alternative for CDA rs2072671 screening where sequencing or Real-Time PCR is not available.

Delineation of the molecular mechanisms of nucleoside recognition by cytidine deaminase through virtual screening.

Cytidine deaminase (EC 3.5.4.5, CDA), an enzyme of the pyrimidine salvage pathways, is responsible for the degradation and inactivation of several cytidine-based antitumor drugs such as cytarabine, gemcitabine, decitabine, and azacytidine. Thus, CDA inhibitors are highly sought after as compounds to be co-administered with said drugs to improve their effectiveness. Alternatively, the design of antitumor drugs not susceptible to the action of CDA is also regarded as an attractive solution. Herein we describe a virtual screen for CDA ligands based on chemical similarity and molecular docking. The campaign led to the identification of three novel inhibitors and one novel substrate, with a 19 % hit rate, and allowed a significant extension of the structure-activity relationships, also in light of the compounds that resulted inactive. The most active compound identified through the screen is the inhibitor pseudoisocytidine, which has the potential to serve as a lead for highly stable compounds. The study also delineated the detrimental effect of 5-aza and 6-aza substitutions, the incompatibility of the presence of an amino group at the 3'-position, as well as the presence of very strict steric requirements around the 2'-arabino position and, even more, the N4-position. Importantly, these features can be exploited for the design of novel anti-neoplastic agents resistant to the action of CDA.

Role of tyrosine 33 residue for the stabilization of the tetrameric structure of human cytidine deaminase.

In the present work the effect of a mutation on tyrosine 33 residue (Y33G) of human cytidine deaminase (CDA) was investigated with regard to protein solubility and specific activity. Osmolytes and CDA ligands were used to increase the yield and the specific activity of the protein. The mutant enzyme was purified and subjected to a kinetic characterization and to stability studies. These investigations reinforced the hypothesis that in human CDA the side chain of Y33 is involved in intersubunit interactions with four glutamate residues (E108) forming a double latch that connects each of the two pairs of monomers of the tetrameric CDA.

PCR-based methods for CDA K27Q and A70T genotyping: genotypes and alleles distribution in a central Italy population.

Cytidine deaminase (CDA) is a pyrimidine salvage pathway enzyme that catalyzes the hydrolytic deamination of cytidine and deoxycytidine to their corresponding uracil nucleosides. CDA also catalyzes the inactivation of some chemotherapeutic nucleoside analogues such as cytosine arabinoside and gemcitabine. CDA 79A > C (K27Q, rs2072671) and 208G > A (A70T, rs60369023) were found to be associated either with clinical outcomes as well as with pharmacokinetics and toxicity of drugs administered to different subsets of patients. In this paper we reported two PCR-based methods for CDA 79A > C (K27Q) and 208G > A (A70T) genotyping and tested their feasibility using DNA extracted from whole blood as well as from buccal swabs. The aim of this study was also to assess the distribution of genotypic variants in a central Italy population. The allele frequencies were 56.3% (K*) and 43.7% (Q*) for K27Q and 100% (A*) and 0% (T*) for A70T. The genotype frequencies were 32.8% (K*/K*), 46.9% (K*/Q*) and 20.3% (Q*/Q*) for K27Q. The genotype frequencies did not deviate from Hardy-Weinberg equilibrium. The results were compared with those of other reported populations. They showed marked ethnic group differences.

CD38 in bovine lung: A multicatalytic NADase.

We report the kinetics and molecular properties of CD38 purified from bovine lung microsomal membranes after its solubilization with Triton X-100. The enzyme was found to be a novel member of a multicatalytic NAD(+)-glycohydrolase (NADase, EC 3.2.2.6). It was able to utilize NAD( + ) in different ways, producing nicotinamide (Nam) and either adenosine diphosphoribose (ADPR, NADase activity) or cyclic ADPR (cADPR, cyclase activity); it also catalyzed the hydrolysis of cADPR to ADPR (cADPR, hydrolase activity). In addition, the enzyme catalyzed the pyridine base exchange reaction with conversion of NAD( + ) into NAD analogues. These data are evidence that CD38 is involved in the regulation of both NAD(+) and calcium-mobilizing agents, the concentration resulting in an essential enzyme that plays a key role in cellular energy and signal-transduction systems.

Human cytidine deaminase: a three-dimensional homology model of a tetrameric metallo-enzyme inferred from the crystal structure of a distantly related dimeric homologue.

Cytidine deaminase (CDA) is a cytosolic metalloprotein whose functional unit can be either a homotetramer (T-CDA) or a homodimer (D-CDA), depending on the species. In 1994, the first crystal structure of the dimeric Escherichia coli CDA has been published. However, a crystal structure of a tetrameric CDA was not determined until 2002. Prior to the disclosure of the experimentally elucidated structure of a tetrameric CDA, we derived a homology model of the human T-CDA employing the crystal structure of the dimeric E. coli CDA as a template. The comparison of our theoretical model with the crystal structure of the human T-CDA, subsequently published in 2004, validates our prediction: not only of the structural features of the monomer and the details of the binding site, but also the multimeric arrangement of the subunits were determined with high accuracy in our model. By means of a phylogenetic analysis conducted on CDAs from various organisms, we demonstrate that the E. coli CDA is one of the furthest known homologues of the human enzyme. Nonetheless, despite the evolutionary distance and, more importantly, the different multimeric arrangement of their functional units, the E. coli CDA proved to have all the necessary information to accurately infer the structure of its human homologue.

Deaza- and deoxyadenosine derivatives: synthesis and inhibition of animal viruses as human infection models.

N6-Cycloalkyl-2',3'-dideoxyadenosine derivatives and (2-chloro)-N6-cycloheptyl-3-deazaadenosine have been synthesized and tested, along with other (deaza)purine (deoxy)nucleosides from our chemical library, as inhibitors of virus replication against Bovine Herpes Virus 1 (BHV-1) and sheep Maedi/Visna Virus (MVV). Most compounds demonstrated good antireplicative activity against MVV, showing also low cell toxicity.

Functional properties of subunit interactions in human cytidine deaminase.

An intersubunit interactions study related to the active site has been performed on the wild-type cytidine deaminase (CDA) and on the mutant enzyme F137W/W113F. F137 is the homologous to the Bacillus subtilis CDA F125 involved in the subunit interactions. In the presence of SDS, wild-type human CDA dissociates into enzymatically inactive monomers without intermediate forms via a non-cooperative transition. Extensive dialysis or dilution of the inactivated monomers restores completely the activity. Circular dichroism measurements show that the secondary/tertiary structure organization of each subunit is unaffected by the SDS concentration, while the mutation Phe/Trp causes weakening in quaternary structure. The presence of the strong human CDA competitive inhibitor 5-fluorozebularine disfavours dissociation of the tetramer into subunits in the wild-type CDA, but not in mutant enzyme F137W/W113F. The absence of tyrosine fluorescence and the much higher quantum yield of the double mutant protein spectrum suggest the occurrence of an energy transfer effect between the protein subunits. This assumption is confirmed by the crystallographic studies on B.subtilis in which it is shown that three different subunits concur with the formation of each of the four active sites and that F125, homologous to the human CDA F137, is located at the interface between two different subunits contributing to the formation of active site.

Adenine and deazaadenine nucleoside and deoxynucleoside analogues: inhibition of viral replication of sheep MVV (in vitro model for HIV) and bovine BHV-1.

A series of N(6)-cycloalkyl-2',3'-dideoxyadenosine derivatives has been prepared by coupling of 2,6-dichloropurine to protected 2,3-dideoxyribose, followed by reaction with appropriate cycloalkylamines. Synthesized compounds, along with other purine nucleoside analogues previously synthesized in our laboratory, have been tested for their antiviral activity against Bovine herpesvirus 1 (BHV-1) and sheep Maedi/Visna Virus (MVV), the latter being an in vitro and in vivo model of Human Immunodeficiency Virus (HIV). All compounds showed good antireplicative activity against MVV, with the N(6)-cycloheptyl-2',3'-dideoxyadenosine (5b) being the most active [effective concentration (EC(50)) causing 50% reduction of cytopatic effects (CPE)=27 nM]. All compounds showed also a from low to very low cell toxicity, resulting in a cytotoxic dose 50 (CD(50))/EC(50) ratio in some cases higher than 1000.