Editing of messenger RNA precursors and of tRNAs by adenosine to inosine conversion.

The double-stranded RNA-specific adenosine deaminases ADAR1 and ADAR2 convert adenosine (A) residues to inosine (I) in messenger RNA precursors (pre-mRNA). Their main physiological substrates are pre-mRNAs encoding subunits of ionotropic glutamate receptors or serotonin receptors in the brain. ADAR1 and ADAR2 have similar sequence features, including double-stranded RNA binding domains (dsRBDs) and a deaminase domain. The tRNA-specific adenosine deaminases Tad1p and Tad2p/Tad3p modify A 37 in tRNA-Ala1 of eukaryotes and the first nucleotide of the anticodon (A 34) of several bacterial and eukaryotic tRNAs, respectively. Tad1p is related to ADAR1 and ADAR2 throughout its sequence but lacks dsRBDs. Tad1p could be the ancestor of ADAR1 and ADAR2. The deaminase domains of ADAR1, ADAR2 and Tad1p are very similar and resemble the active site domains of cytosine/cytidine deaminases.     

Intracellular localization of human cytidine deaminase. Identification of a functional nuclear localization signal.

The cytidine deaminases belong to the family of multisubunit enzymes that catalyze the hydrolytic deamination of their substrate to a corresponding uracil product. They play a major role in pyrimidine nucleoside and nucleotide salvage. The intracellular distribution of cytidine deaminase and related enzymes has previously been considered to be cytosolic. Here we show that human cytidine deaminase (HCDA) is present in the nucleus. A highly specific, affinity purified polyclonal antibody against HCDA was used to analyze the intracellular localization of native HCDA in a variety of mammalian cells by in situ immunochemistry. Native HCDA was found to be present in the nucleus as well as the cytoplasm in several cell types. Indirect immunofluorescence microscopy indicated a predominantly nuclear localization of FLAG-tagged HCDA overexpressed in these cells. We have identified an amino-terminal bipartite nuclear localization signal that is both necessary and sufficient to direct HCDA and a non-nuclear reporter protein to the nucleus. We also show HCDA binding to the nuclear import receptor, importin alpha. Similar putative bipartite nuclear localization sequences are found in other cytidine/deoxycytidylate deaminases. The results presented here suggest that the pyrimidine nucleotide salvage pathway may operate in the nucleus. This localization may have implications in the regulation of nucleoside and nucleotide metabolism and nucleic acid biosynthesis.     

Arabidopsis thaliana cytidine deaminase 1 shows more similarity to prokaryotic enzymes than to eukaryotic enzymes

Two Expressed Sequence Tagged (EST) clones were identified from the Arabidopsis database as encoding putative cytidine deaminases. Sequence analysis determined that the two clones overlapped and encoded a single cDNA. This cytidine deaminase corresponds to theArabidopsis thaliana gene,cda1. The deduced amino acid sequence was more closely related to prokaryotic cytidine deaminases than to eukaryotic enzymes. The cDNA shares 44% amino acid identity with theEscherichia coli cytidine deaminase but only 26 and 27% identity with human and yeast enzymes. A unique zinc-binding domain of the Ecoli enzyme forms the active site. A similar putative zinc-binding domain was identified in the Arabidopsis enzyme based upon primary sequence similarities. These similarities permitted us to model the active site of the Arabidopsis enzyme upon that of the Ecoli enzyme. In this model, the active site zinc is coordinated by His⁷³, Cys¹⁰³, Cys¹⁰⁷, and an active site hydroxyl. Additional residues that participate in catalysis, Asn⁶⁴, Glu⁶⁶, Ala⁷⁸, Glu⁷⁹, and Pro¹⁰², are conserved between the Arabidopsis and Ecoli enzymes suggesting that the Arabidopsis enzyme has a catalytic mechanism similar to the Ecoli enzyme. The two overlapping ESTs were used to prepare a single, full-length clone corresponding to theA thaliana cda1 cDNA. This cDNA was subcloned into pProExHtb and expressed as a fusion protein with an N-terminal His₆ tag. Following purification on a Ni-NTA-Agarose column, the protein was analyzed for its kinetic properties. The enzyme utilizes both cytidine (K_m = 226 μand 2’-deoxycytidine (K_m= 49 μM) as substrates. The enzyme was unable to deaminate cytosine, CMP or dCMP. journal Paper Number J-18324 of the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa Project No. 3340.     

Sub-families of alpha/beta barrel enzymes: a new adenine deaminase family

No gene coding for an adenine deaminase has been described in eukaryotes. However, physiological and genetical evidence indicates that adenine deaminases are present in the ascomycetes. We have cloned and characterised the genes coding for the adenine deaminases of Aspergillus nidulans, Saccharomyces cerevisiae and Schizosaccharomyces pombe. The A.nidulans gene was expressed in Escherichia coli and the purified enzyme shows adenine but not adenosine deaminase activity. The open reading frames coded by the three genes are very similar and obviously related to the bacterial and eukaryotic adenosine deaminases rather than to the bacterial adenine deaminases. The latter are related to allantoinases, ureases and dihydroorotases. The fungal adenine deaminases and the homologous adenosine deaminases differ in a number of residues, some of these being clearly involved in substrate specificity. Other prokaryotic enzymes in the database, while clearly related to the above, do not fit into either sub-class, and may even have a different specificity. These results imply that adenine deaminases have appeared twice in the course of evolution, from different ancestral enzymes constructed both around the alpha/beta barrel scaffold.     

Vertebrate immunity: mutator proteins and their evolution

M.E. Lobashev has brilliantly postulated in 1947 that error-prone repair contribute to mutations in cells. This was shown to be true once the mechanisms of UV mutagenesis in Escherichia coli were deciphered. Induced mutations are generated during error-prone SOS DNA repair with the involvement of inaccurate DNA polymerases belonging to the Y family. Currently, several distinct mutator enzymes participating in spontaneous and induced mutagenesis have been identified. Upon induction of these proteins, mutation rates increase by several orders of magnitude. These proteins regulate the mutation rates in evolution and in ontogeny during immune response. In jawed vertebrates, somatic hypermutagenesis occurs in the variable regions of immunoglobulin genes, leading to affinity maturation of antibodies. The process is initiated by cytidine deamination in DNA to uracil by AID (Activation-Induced Deaminase). Further repair of uracil-containing DNA through proteins that include the Y family DNA polymerases causes mutations, induce gene conversion, and class switch recombination. In jawless vertebrates, the variable lymphocyte receptors (VLR) serve as the primary molecules for adaptive immunity. Generation of mature VLRs most likely depends on agnathan AID-like deaminases. AID and its orthologs in lamprey (PmCDA1 and PMCDA2) belong to the AID/APOBEC family of RNA/DNA editing cytidine deaminases. This family includes enzymes with different functions: APOBEC1 edits RNA, APOBEC3 restricts retroviruses. The functions of APOBEC2 and APOBEC4 have not been yet determined. Here, we report a new member of the AID/APOBEC family, APOBEC5, in the bacterium Xanthomonas oryzae. The widespread presence of RNA/DNA editing deaminases suggests that they are an ancient means of generating genetic diversity.     

APOBEC deaminases-mutases with defensive roles for immunity

In recent years, tremendous progress has been made in the elucidation of the biological roles and molecular mechanisms of the apolioprotein B mRNA-editing enzyme catalytic polypeptide (APOBEC) family of enzymes. The APOBEC family of cytidine deaminases has important functional roles within the adaptive and innate immune system. Activation induced cytidine deaminase (AID) plays a central role in the biochemical steps of somatic hypermutation and class switch recombination during antibody maturation, and the APOBEC 3 enzymes are able to inhibit the mobility of retroelements and the replication of retroviruses and DNA viruses, such as the human immunodeficiency virus type-1 and hepatitis B virus. Recent advances in structural and functional studies of the APOBEC enzymes provide new biochemical insights for how these enzymes carry out their biological roles. In this review, we provide an overview of these recent advances in the APOBEC field with a special emphasis on AID and APOBEC3G.     

APOBEC-2, a cardiac- and skeletal muscle-specific member of the cytidine deaminase supergene family.

APOBEC-1, which mediates the editing of apolipoprotein (apo) B mRNA, is the only known member of the C (cytidine)-->U (uridine) editing enzyme subfamily of the cytidine deaminase supergene family. Here we report the cloning of APOBEC-2, another member of the subfamily. Human and mouse APOBEC-2 both contain 224 amino acid residues, and their genes are mapped to syntenic regions of human chromosome 6 (6p21) and mouse chromosome 17. By phylogenetic analysis, APOBEC-2 is shown to be evolutionarily related to APOBEC-1, and analysis of substitution rates indicates that APOBEC-2 is a much better conserved gene than APOBEC-1. APOBEC-2 mRNA and protein are expressed exclusively in heart and skeletal muscle. APOBEC-2 does not display detectable apoB mRNA editing activity. Like other editing enzymes of the cytidine deaminase superfamily, APOBEC-2 has low, but definite, intrinsic cytidine deaminase activity. The identification of APOBEC-2 indicates that APOBEC-1 is not the only member of the C-->U editing enzyme subfamily, which, like the A (adenosine)-->I (inosine) subfamily of editing enzymes, must encompass at least two and possibly more different deaminase enzymes. It suggests that the C-->U editing affecting apoB mRNA and other RNAs is not an isolated event mediated by a single enzyme but involves multiple related proteins that have evolved from a primordial gene closely related to the housekeeping enzyme cytidine deaminase.     

A member of the second carbohydrate uptake subfamily of ATP-binding cassette transporters is responsible for ribonucleoside uptake in Streptococcus mutans

Streptococcus mutans has a significant number of transporters of the ATP-binding cassette (ABC) superfamily. Members of this superfamily are involved in the translocation of a diverse range of molecules across membranes. However, the functions of many of these members remain unknown. We have investigated the role of the single S. mutans representative of the second subfamily of carbohydrate uptake transporters (CUT2) of the ABC superfamily. The genetic context of genes encoding this transporter indicates that it may have a role in ribonucleoside scavenging. Inactivation of rnsA (ATPase) or rnsB (solute binding protein) resulted in strains resistant to 5-fluorocytidine and 5-fluorouridine (toxic ribonucleoside analogues). As other ribonucleosides including cytidine, uridine, adenosine, 2-deoxyuridine, and 2-deoxycytidine protected S. mutans from 5-fluorocytidine and 5-fluorouridine toxicity, it is likely that this transporter is involved in the uptake of these molecules. Indeed, the rnsA and rnsB mutants were unable to transport [2-(14)C]cytidine or [2-(14)C]uridine and had significantly reduced [8-(14)C]adenosine uptake rates. Characterization of this transporter in wild-type S. mutans indicates that it is a high-affinity (K(m) = 1 to 2 muM) transporter of cytidine, uridine, and adenosine. The inhibition of [(14)C]cytidine uptake by a range of structurally related molecules indicates that the CUT2 transporter is involved in the uptake of most ribonucleosides, including 2-deoxyribonucleosides, but not ribose or nucleobases. The characterization of this permease has directly shown for the first time that an ABC transporter is involved in the uptake of ribonucleosides and extends the range of substrates known to be transported by members of the ABC transporter superfamily.     

Antiviral defense by APOBEC3 family proteins

APOBEC3G is a potent antiretroviral factor, which belongs to the APOBEC superfamily of cytidine deaminases. It deaminates cytidine to uridine in nascent minus-strand viral DNA, inducing G-to-A hypermutation in the plus-strand viral DNA. HIV-1 Vif protein overcomes the antiviral activity of APOBEC3G by targeting it for ubiquitin-dependent degradation. Recent accumulating evidences that other members of APOBEC proteins also show antiviral activity on a wide variety of viruses suggest that APOBEC family proteins play a crucial role in an antiviral defense as an innate immunity. Here, we review recent progress in research on APOBEC3 proteins.     

Reward versus risk: DNA cytidine deaminases triggering immunity and disease

The enzymatic deamination of cytosine to uracil, using the free base C, its nucleosides, and nucleotides as substrates, is an essential feature of nucleotide metabolism. However, the deamination of C and, especially, 5 methyl C on DNA is typically detrimental, causing mutations leading to serious human disease. Recently, a family of enzymes has been discovered that catalyzes the conversion of C to U on DNA and RNA, generating favorable mutations that are essential for human survival. Members of the Apobec family of nucleic acid-dependent cytidine deaminases include activation-induced cytidine deaminase (AID) and Apobec3G. AID is required for B cells to undergo somatic hypermutation (SHM) and class switch recombination (CSR), two processes that are needed to produce high-affinity antibodies of all isotypes. Apobec3G is responsible for protection against HIV infection. Recent advances in the biochemical and structural analyses of nucleic acid cytidine deaminases will be discussed in relation to their programmed roles in ensuring antibody diversification and in imposing innate resistance against retroviral infection. The serious negative consequences of expressing Apobec deaminases in the wrong place at the wrong time to catalyze aberrant deamination in "at risk" sequences will be discussed in terms of causing genomic instability and disease.     

Pa0148 from Pseudomonas aeruginosa catalyzes the deamination of adenine

Four proteins from NCBI cog1816, previously annotated as adenosine deaminases, have been subjected to structural and functional characterization. Pa0148 (Pseudomonas aeruginosa PAO1), AAur1117 (Arthrobacter aurescens TC1), Sgx9403e, and Sgx9403g have been purified and their substrate profiles determined. Adenosine is not a substrate for any of these enzymes. All of these proteins will deaminate adenine to produce hypoxanthine with k(cat)/K(m) values that exceed 10(5) M(-1) s(-1). These enzymes will also accept 6-chloropurine, 6-methoxypurine, N-6-methyladenine, and 2,6-diaminopurine as alternate substrates. X-ray structures of Pa0148 and AAur1117 have been determined and reveal nearly identical distorted (β/α)(8) barrels with a single zinc ion that is characteristic of members of the amidohydrolase superfamily. Structures of Pa0148 with adenine, 6-chloropurine, and hypoxanthine were also determined, thereby permitting identification of the residues responsible for coordinating the substrate and product.     

Requirement of dimerization for RNA editing activity of adenosine deaminases acting on RNA

Adenosine deaminases acting on RNA (ADAR) convert adenosine residues into inosines in double-stranded RNA. Three vertebrate ADAR gene family members, ADAR1, ADAR2, and ADAR3, have been identified. The catalytic domain of all three ADAR gene family members is very similar to that of Escherichia coli cytidine deaminase and APOBEC-1. Homodimerization is essential for the enzyme activity of those cytidine deaminases. In this study, we investigated the formation of complexes between differentially epitope-tagged ADAR monomers by sequential affinity chromatography and size exclusion column chromatography. Both ADAR1 and ADAR2 form a stable enzymatically active homodimer complex, whereas ADAR3 remains as a monomeric, enzymatically inactive form. No heterodimer complex formation among different ADAR gene family members was detected. Analysis of HeLa and mouse brain nuclear extracts suggested that endogenous ADAR1 and ADAR2 both form a homodimer complex. Interestingly, endogenous ADAR3 also appears to form a homodimer complex, indicating the presence of a brain-specific mechanism for ADAR3 dimerization. Homodimer formation may be necessary for ADAR to act as active deaminases. Analysis of dimer complexes consisting of one wild-type and one mutant monomer suggests functional interactions between the two subunits during site-selective RNA editing.     

Crystal structure of Bacillus subtilis guanine deaminase: the first domain-swapped structure in the cytidine deaminase superfamily

Guanine deaminase, a key enzyme in the nucleotide metabolism, catalyzes the hydrolytic deamination of guanine into xanthine. The crystal structure of the 156-residue guanine deaminase from Bacillus subtilis has been solved at 1.17-A resolution. Unexpectedly, the C-terminal segment is swapped to form an intersubunit active site and an intertwined dimer with an extensive interface of 3900 A(2) per monomer. The essential zinc ion is ligated by a water molecule together with His(53), Cys(83), and Cys(86). A transition state analog was modeled into the active site cavity based on the tightly bound imidazole and water molecules, allowing identification of the conserved deamination mechanism and specific substrate recognition by Asp(114) and Tyr(156'). The closed conformation also reveals that substrate binding seals the active site entrance, which is controlled by the C-terminal tail. Therefore, the domain swapping has not only facilitated the dimerization but has also ensured specific substrate recognition. Finally, a detailed structural comparison of the cytidine deaminase superfamily illustrates the functional versatility of the divergent active sites found in the guanine, cytosine, and cytidine deaminases and suggests putative specific substrate-interacting residues for other members such as dCMP deaminases.     

Adenosine deaminase in chicken-egg yolk and its relation to homologous enzymes in liver and plasma of the adult hen.

Chicken egg yolk contains an adenosine deaminase that was investigated after purifying about 500 times. It has a pH optimum at 6.5, aKm of 6.6 times 10(-5) mol/l and an approximate molecular weight of 14000; higher molecular forms could not be detected. It was compared with the adenosine deaminases of chicken liver and blood plasma. From this comparison it is evident that this protein has undergone certain changes during the successive events leading to its final structure (secretion by the liver, transport through blood plasma to the oocytes and development of the egg): a common subunit with an approximate molecular weight of 15000 may be the basis of the physiological diversifications. Substrate specificity of the purified extracts extends to cytidine and guanosine also, although certain observations point to different enzymes being involved. Deoxyadenosine is also deaminated. Cu2+, Zn2+, and Pb2+ are inhibiting and free -SH seems essential for activity.     

ADAR2 A-->I editing: site selectivity and editing efficiency are separate events

ADAR enzymes, adenosine deaminases that act on RNA, form a family of RNA editing enzymes that convert adenosine to inosine within RNA that is completely or largely double-stranded. Site-selective A→I editing has been detected at specific sites within a few structured pre-mRNAs of metazoans. We have analyzed the editing selectivity of ADAR enzymes and have chosen to study the naturally edited R/G site in the pre-mRNA of the glutamate receptor subunit B (GluR-B). A comparison of editing by ADAR1 and ADAR2 revealed differences in the specificity of editing. Our results show that ADAR2 selectively edits the R/G site, while ADAR1 edits more promiscuously at several other adenosines in the double-stranded stem. To further understand the mechanism of selective ADAR2 editing we have investigated the importance of internal loops in the RNA substrate. We have found that the immediate structure surrounding the editing site is important. A purine opposite to the editing site has a negative effect on both selectivity and efficiency of editing. More distant internal loops in the substrate were found to have minor effects on site selectivity, while efficiency of editing was found to be influenced. Finally, changes in the RNA structure that affected editing did not alter the binding abilities of ADAR2. Overall these findings suggest that binding and catalysis are independent events.     

Incarnation of classical pro- and eukaryotic mechanisms of mutagenesis in hypermutagenesis and immunity of vertebrates

M.E. Lobashev has brilliantly postulated in 1947 that error-prone repair contribute to mutations in cells. This was shown to be true once the mechanisms of UV mutagenesis in Escherichia coli were deciphered. Induced mutations are generated during error-prone SOS DNA repair with the involvement of inaccurate DNA polymerases belonging to the Y family. Currently, several distinct mutator enzymes participating in spontaneous and induced mutagenesis have been identified. Upon induction of these proteins, mutation rates increase by several orders of magnitude. These proteins regulate the mutation rates in evolution and in ontogeny during immune response. In jawed vertebrates, somatic hypermutagenesis occurs in the variable regions of immunoglobulin genes, leading to affinity maturation of antibodies. The process is initiated by cytidine deamination in DNA to uracil by AID (Activation-Induced Deaminase). Further repair of uracil-containing DNA through proteins that include the Y family DNA polymerases causes mutations, induce gene conversion, and class switch recombination. In jawless vertebrates, the variable lymphocyte receptors (VLR) serve as the primary molecules for adaptive immunity. Generation of mature VLRs most likely depends on agnathan AID-like deaminases. AID and its orthologs in lamprey (PmCDA1 and PMCDA2) belong to the AID/APOBEC family of RNA/DNA editing cytidine deaminases. This family includes enzymes with different functions: APOBEC1 edits RNA, APOBEC3 restricts retroviruses. The functions of APOBEC2 and APOBEC4 have not been yet determined. Here, we report a new member of the AID/APOBEC family, APOBEC5, in the bacterium Xanthomonas oryzae. The widespread presence of RNA/DNA editing deaminases suggests that they are an ancient means of generating genetic diversity.     

Natural variation in Vif: differential impact on APOBEC3G/3F and a potential role in HIV-1 diversification

The HIV-1 Vif protein counteracts the antiviral activity exhibited by the host cytidine deaminases APOBEC3G and APOBEC3F. Here, we show that defective vif alleles can readily be found in HIV-1 isolates and infected patients. Single residue changes in the Vif protein sequence are sufficient to cause the loss of Vif-induced APOBEC3 neutralization. Interestingly, not all the detected defects lead to a complete inactivation of Vif function since some mutants retained selective neutralizing activity against APOBEC3F but not APOBEC3G or vice versa. Concordantly, independently hypermutated proviruses with distinguishable patterns of G-to-A substitution attributable to cytidine deamination induced by APOBEC3G, APOBEC3F, or both enzymes were present in individuals carrying proviruses with completely or partly defective Vif variants. Natural variation in Vif function may result in selective and partial neutralization of cytidine deaminases and thereby promote viral sequence diversification within HIV-1 infected individuals.