Double modification of cytidine residues in DNA]

The reaction of O-beta-diethylaminoethylhydroxylamine (O-beta-HA) with cytidine was studied and its mechanism was shown to be analogous to that of the reaction of hydroxylamine of O-methylhydroxylamine with cytidine. In experiments involving reaction of denatured DNA with O-beta-HA., Sephadex G-15 columns were used for the quantitative separation of normal and modified nucleosides after enzymatic hydrolysis of modified DNA by exonuclease A5 followed by alkaline phosphatase treatment. DNA cytidine residues of free cytidine with O-beta-HA. Modified cytidines can form complex with phosphotungstic acid (PTA). It was shown that one mole of PTA was bound per one mole of modified cytidine either in DNA or in free state. Electron microscopic examination of denatured DNA molecules modified by O-beta-HA and reacted with PTA revealed linear arrays of electron-scattering spots which presumably correspond to PTA molecules complexed with modified cytidine in DNA chains.     

Reaction of cytidine with semicarbazide in the presence of bisulfite. A rapid modification specific for single-stranded polynucleotide.

Semicarbazide reacted rapidly with 5,6-dihydrocytidine-6-sulfonate, which was formed from cytidine by addition of bisulfite across the 5,6-double bond. The transaminated product, 5,6-dihydro-4-semicarbazido-2-ketotopyrimidine-6-sulfonate ribofuranoside, was identified by comparison with that formed by treatment of 4-semicarbazido-2-ketopyrimidine ribofuranoside with bisulfite. The progress of the transamination was monitored spectrophotometrically by use of a strong absorbance of the product in alkali. The reaction between cytidine and the semicarbazide-bisulfite mixture was optimal at pH 4.5. Complete transformation of cytidine into the product required only 5 min with the use of 3M semicarbazide-1M sodium bisulfite, pH 5.0, at the reaction temperature 37 degrees C. The product was stable in unbuffered solution but in phosphate buffers it underwent elimination of bisulfite to give 4-semicarbazido-2-ketopyrimidine ribofuranoside. The rate of the elimination at pH 7.0 and 37 degrees C increased proportionally with the increase of the phosphate concentration. Complete elimination was obtained by treatment with 1 M sodium phosphate for 2 h. When heat-denatured calf-thymus DNA was treated with 3 M semicarbazide-1 M bisulfite at 37 degrees C and pH 5.0 the transamination of reactive cytosine residues was completed by 10 min of incubation. At 20 degrees C, it required 85 min of incubation. Cytosine residues in native DNA did not react at all even by prolonged incubations. The modified DNA samples were further treated with a phosphate buffer at pH 7, producing 4-semicarbazido-2-ketopyrimidine residues in the DNA. Analysis of the base compositions of these samples by perchloric acid hydrolysis showed that the modification was selective to cytosine, which had been expected from studies with monomers. It also showed that the reactive cytosine residues in the denatured DNA, constitute about 80% of the total cytosine, which was consistent with the view that heat-denatured DNA still contains a considerable amount of secondary structure. The semicarbazide-bisulfite modification is expected to be a sensitive method to locate cytosine residues in single-stranded regions of polynucleotides.     

Construction of DNA-probes and their immunochemical detection using nonradioactive hybridization tests

Simple and efficient chemical approaches to preparation of DNA probes carrying 2,4-dinitrophenyl, dansyl or biotin residues were developed. The residues were introduced using following DNA derivatization procedures: a) transamination of cytidine residues with O-(4-aminobutyl)hydroxylamine; b) mercuration of pyrimidine residues followed by beta-mercaptoethanol modification. It was shown that 2,4-dinitrophenyl-containing DNA probes can be used for nonradioactive hybridization detection of nucleic acids. DNP-DNA: DNA complexes were detected using mouse antibodies specific to 2,4-dinitrophenyl groups, which were developed with peroxidase-conjugated antimouse immunoglobulins. Peroxidase-catalyzed chemoluminescent reaction of luminol oxidation with hydrogen peroxide allowed to detect 10 picograms of the dinitrophenylated single-stranded DNA probe.     

Effects of nucleotide bromination on the stabilities of Z-RNA and Z-DNA: a molecular mechanics/thermodynamic perturbation study

The structures of ZI- and ZII-form RNA and DNA oligonucleotides were energy minimized in vacuum using the AMBER molecular mechanics force field. Alternating C-G sequences were studied containing either unmodified nucleotides, 8-bromoguanosine in place of all guanosine residues, 5-bromocytidine in place of all cytidine residues, or all modified residues. Some molecules were also energy minimized in the presence of H2O and cations. Free energy perturbation calculations were done in which G8 and C5 hydrogen atoms in one or two residues of Z-form RNAs and DNAs were replaced in a stepwise manner by bromines. Bromination had little effect on the structures of the energy-minimized molecules. Both the minimized molecular energies and the results of the perturbation calculations indicate that bromination of guanosine at C8 will stabilize the Z forms of RNA and DNA relative to the nonbrominated Z form, while bromination of cytidine at C5 stabilizes Z-DNA and destabilizes Z-RNA. These results are in agreement with experimental data. The destabilizing effect of br5C in Z-RNAs is apparently due to an unfavorable interaction between the negatively charged C5 bromine atom and the guanosine hydroxyl group. The vacuum-minimized energies of the ZII-form oligonucleotides are lower than those of the corresponding ZI-form molecules for both RNA and DNA. Previous x-ray diffraction, nmr, and molecular mechanics studies indicate that hydration effects may favor the ZI conformation over the ZII form in DNA. Molecular mechanics calculations show that the ZII-ZI energy differences for the RNAs are greater than three times those obtained for the DNAs. This is due to structurally reinforcing hydrogen-bonding interactions involving the hydroxyl groups in the ZII form, especially between the guanosine hydroxyl hydrogen atom and the 3'-adjacent phosphate oxygen. In addition, the cytidine hydroxyl oxygen forms a hydrogen bond with the 5'-adjacent guanosine amino group in the ZII-form molecule. Both of these interactions are less likely in the ZI-form molecule: the former due to the orientation of the GpC phosphate away from the guanosine ribose in the ZI form, and the latter apparently due to competitive hydrogen bonding of the cytidine 2'-hydroxyl hydrogen with the cytosine carbonyl oxygen in the ZI form. The hydrogen-bonding interaction between the cytidine hydroxyl oxygen and the 5'-adjacent guanosine amino group in Z-RNA twists the amino group out of the plane of the base. This may be responsible for differences in the CD and Raman spectra of Z-RNA and Z-DNA.     

C-terminal deletion of AID uncouples class switch recombination from somatic hypermutation and gene conversion

Class-switch recombination (CSR), somatic hypermutation (SHM), and antibody gene conversion are distinct DNA modification reactions, but all are initiated by activation-induced cytidine deaminase (AID), an enzyme that deaminates cytidine residues in single-stranded DNA. Here we describe a mutant form of AID that catalyzes SHM and gene conversion but not CSR. When expressed in E. coli, AID(delta189-198) is more active in catalyzing cytidine deamination than wild-type AID. AID(delta189-198) also promotes high levels of gene conversion and SHM when expressed in eukaryotic cells, but fails to induce CSR. These results underscore an essential role for the C-terminal domain of AID in CSR that is independent of its cytidine deaminase activity and that is not required for either gene conversion or SHM.     

13C relaxation studies of the DNA target sequence for hhai methyltransferase reveal unique motional properties

The goal of this work was to examine if sequence-dependent conformational flexibility in DNA plays a role in base extrusion, a common conformational change induced by many DNA-modifying enzymes. We studied the dynamics of the double-stranded DNA target of the HhaI methyltransferase by recording an extensive set of (13)C NMR relaxation parameters. We observe that the cytidine furanose rings experience fast (picosecond to nanosecond) motions that are not present in other nucleotides; the methylation site experiences particularly high mobility. We also observe that the bases of guanosine and cytidine residues within the HhaI recognition sequence GCGC experience motions on a much slower (1-100 micros) time scale. We compare these observations with previous solution and solid-state NMR studies of the EcoRI nuclease target sequence, and solid-state NMR studies of a similar HhaI target construct. While an increased mobility of cytidine furanose rings compared to those of other nucleotides is observed for both sequences, the slower motions are only observed in the HhaI target DNA. We propose that this inherent flexibility lowers the energetic barriers that must occur when the DNA binds to the HhaI methyltransferase and for extrusion of the cytidine prior to its methylation.     

Reactivity of potassium permanganate and tetraethylammonium chloride with mismatched bases and a simple mutation detection protocol

Many mutation detection techniques rely upon recognition of mismatched base pairs in DNA hetero-duplexes. Potassium permanganate in combination with tetraethylammonium chloride (TEAC) is capable of chemically modifying mismatched thymidine residues. The DNA strand can then be cleaved at that point by treatment with piperidine. The reactivity of potassium permanganate (KMnO4) in TEAC toward mismatches was investigated in 29 different mutations, representing 58 mismatched base pairs and 116 mismatched bases. All mismatched thymidine residues were modified by KMnO4/TEAC with the majority of these showing strong reactivity. KMnO4/TEAC was also able to modify many mismatched guanosine and cytidine residues, as well as matched guanosine, cytidine and thymidine residues adjacent to, or nearby, mismatched base pairs. Previous techniques using osmium tetroxide (OsO4) to modify mismatched thymidine residues have been limited by the apparent lack of reactivity of a third of all T/G mismatches. KMnO4/TEAC showed no such phenomenon. In this series, all 29 mutations were detected by KMnO4/TEAC treatment. The latest development of the Single Tube Chemical Cleavage of Mismatch Method detects both thymidine and cytidine mismatches by KMnO4/TEAC and hydroxylamine (NH2OH) in a single tube without a clean-up step in between the two reactions. This technique saves time and material without disrupting the sensitivity and efficiency of either reaction.     

Attachment of reporter groups to specific, selected cytidine residues in RNA using a bisulfite-catalyzed transamination reaction.

Bisulfite catalyzes transamination of cytidine at the N4 position; the suitability of this reaction for attaching reporter groups to selected cytidine residues in RNA molecules has been investigated. Poly(C) is nearly quantitatively converted to the poly (N4 aminoethyl-C) derivative after 3 hrs at 42 degrees C with ethylene diamine (pK1 = 7.6) and bisulfite. This derivative reacts quantitatively with N-hydroxysuccinimide esters; the linkage of a fluorescent dye, nitrobenzofurazan, to cytidine by this reaction is demonstrated. To direct the bisulfite reaction to selected cytidines within a large RNA molecule, the RNA is hybridized to complementary DNA containing a deletion. Only the cytidines in the single strand RNA loop (corresponding to the DNA deletion) are reactive. Two cytidines in the middle of a 340 base RNA fragment from 16S ribosomal RNA have been modified by this technique.     

Evidence on the conformation of HeLa-cell 5.8S ribosomal ribonucleic acid from the reaction of specific cytidine residues with sodium bisulphite.

The reaction of HeLa-cell 5.8S rRNA with NaHSO3 under conditions in which exposed cytidine residues are deaminated to uridine was studied. It was possible to estimate the reactivities of most of the 46 cytidine residues in the nucleotide sequence by comparing 'fingerprints' of the bisulphite-treated RNA with those of untreated RNA. The findings were consistent with the main features of the secondary-structure model for mammalian 5.85S rRNA proposed by Nazar, Sitz, & Busch [J. Biol. Chem (1975) 250, 8591--8597]. Five out of six regions that are depicted in the model as single-stranded loops contain cytidine residues that are reactive towards bisulphite at 25 degrees C (the other loop contains no cytidine). The cytidine residue nearest to the 3'-terminus is also reactive. Several cytidines residues that are internally located within proposed double-helical regions show little or no reactivity towards bisulphite, but the cytidine residues of several C.G pairs at the ends of helical regions show some reactivity, and one of the proposed loops appears to contain six nucleotides, rather than the minimum of four suggested by the primary structure. Two cytidine residues that are thought to be 'looped out' by small helix imperfections also show some reactivity.     

Specific binding of o-phenanthroline at a DNA structural lesion.

DNA intercalators are found to recognize a DNA lesion as a high affinity receptor site. This lesion-specific binding is observed when one strand of a DNA double helix contains an extra, unpaired nucleotide. Our assay for binding controls for the effects of sequence with a series of oligodeoxynucleotide duplexes which are identical except for the location of the lesion, an extra cytidine. Scission of the series of oligodeoxynucleotides by the cuprous complex of ortho-phenanthroline (OP-Cu) indicates that OP-Cu binds at the lesion-specific stable intercalation site, suggesting that OP-Cu intercalates into DNA. The dispersion of OP-Cu scission sites over three residues is consistent with scission via a diffusible intermediate. The location of the scission sites, directly on the 3' side of the lesion, is consistent with minor groove binding in B DNA.     

An Extended Structure of the APOBEC3G Catalytic Domain Suggests a Unique Holoenzyme Model

Human APOBEC3G (A3G) belongs to a family of polynucleotide cytidine deaminases. This family includes APOBEC1 and AID, which edit APOB mRNA and antibody gene DNA, respectively. A3G deaminates cytidines to uridines in single-strand DNA and inhibits the replication of human immunodeficiency virus-1, other retroviruses, and retrotransposons. Although the mechanism of A3G-catalyzed DNA deamination has been investigated genetically and biochemically, atomic details are just starting to emerge. Here, we compare the DNA cytidine deaminase activities and NMR structures of two A3G catalytic domain constructs. The longer A3G191-384 protein is considerably more active than the shorter A3G198-384 variant. The longer structure has an α1-helix (residues 201-206) that was not apparent in the shorter protein, and it contributes to catalytic activity through interactions with hydrophobic core structures (β1, β3, α5, and α6). Both A3G catalytic domain solution structures have a discontinuous β2 region that is clearly different from the continuous β2 strand of another family member, APOBEC2. In addition, the longer A3G191-384 structure revealed part of the N-terminal pseudo-catalytic domain, including the interdomain linker and some of the last α-helix. These structured residues (residues 191-196) enabled a novel full-length A3G model by providing physical overlap between the N-terminal pseudo-catalytic domain and the new C-terminal catalytic domain structure. Contrary to predictions, this structurally constrained model suggested that the two domains are tethered by structured residues and that the N- and C-terminal β2 regions are too distant from each other to participate in this interaction.     

RNA-Dependent Oligomerization of APOBEC3G Is Required for Restriction of HIV-1

The human cytidine deaminase APOBEC3G (A3G) is a potent inhibitor of retroviruses and transposable elements and is able to deaminate cytidines to uridines in single-stranded DNA replication intermediates. A3G contains two canonical cytidine deaminase domains (CDAs), of which only the C-terminal one is known to mediate cytidine deamination. By exploiting the crystal structure of the related tetrameric APOBEC2 (A2) protein, we identified residues within A3G that have the potential to mediate oligomerization of the protein. Using yeast two-hybrid assays, co-immunoprecipitation, and chemical crosslinking, we show that tyrosine-124 and tryptophan-127 within the enzymatically inactive N-terminal CDA domain mediate A3G oligomerization, and this coincides with packaging into HIV-1 virions. In addition to the importance of specific residues in A3G, oligomerization is also shown to be RNA-dependent. Homology modelling of A3G onto the A2 template structure indicates an accumulation of positive charge in a pocket formed by a putative dimer interface. Substitution of arginine residues at positions 24, 30, and 136 within this pocket resulted in reduced virus inhibition, virion packaging, and oligomerization. Consistent with RNA serving a central role in all these activities, the oligomerization-deficient A3G proteins associated less efficiently with several cellular RNA molecules. Accordingly, we propose that occupation of the positively charged pocket by RNA promotes A3G oligomerization, packaging into virions and antiviral function.     

Reaction of HeLa cell methyl-labelled 28S ribosomal RNA with sodium bisulphite: a conformational probe for methylated sequences.

The reaction of 14C methyl-labelled HeLa cell 28 S ribosomal RNA with sodium bisulphite was studied. Using conditions under which 30% of the total cytidine residues were de-aminated to uridine, the reactivities of individual cytidine residues near particular methylation sites differed widely; some underwent almost quantitative reaction, some showed intermediate reactivity and others were almost inert. The possible value of this method as a conformational probe for ribosomal RNA is discussed.     

Local mobility of nucleic acids as determined from crystallographic data. II. Z-form DNA

Directions and magnitudes of the local mobility of the Z-DNA hexamer duplex CpGpCpGpCpG have been determined by crystallographic refinement of anisotropic displacement parameters using the observed X-ray diffraction data. The cytidine and guanosine residues demonstrate different modes of mobility, implying that a dinucleotide is the smallest repeating unit in terms of flexibility as well as structure. Directions of librational and translational mobility of the cytidine and guanosine residues of Z-DNA are similar to those observed for the same nucleotides in B-DNA. This suggests that the local mobility of DNA is primarily determined by the individual nucleotide type and by the constraints of Watson-Crick base-pairing, rather than by helical form. Differences in the magnitudes of mobility may be responsible for some of the different physical properties of B-DNA and Z-DNA. The B to Z transition is discussed in terms of the observed flexibilities of these two helical forms.     

Role of ribonucleic acid synthesis in conjugational transfer of chromosomal and plasmid deoxyribonucleic acids

A strain of Escherichia coli K-12 containing mutations that allow for the experimental control of RNA and DNA syntheses was constructed to investigate the role that RNA synthesis plays in conjugational DNA transfer when DNA replication is inhibited. The mutations possessed by this strain and its donor derivatives include: (i) thyA, which blocks synthesis of dTMP, causing a requirement for thymine; (ii) deoC, which blocks breakdown of deoxyribose 5-phosphate, permitting growth with low levels of thymine; (iii) pyrF, which blocks synthesis of UMP from OMP, imposing a requirement for uridine; (iv) cdd and pyrG, which block the deamination of cytidine to uridine and the synthesis of CTP from UTP, respectively, causing a requirement for cytidine; (v) codA and codB, which block the deamination of cytosine to uracil and cytosine transport, respectively, preventing the substitution of cytosine for cytidine; and (vi) dnaB, which blocks vegetative but not conjugational DNA replication at 42 degrees C. DNA synthesis can be blocked in the donor strains by the addition of excess uridine when exogenous thymine is not present. We found that RNA synthesis can also be blocked by addition of excess uridine when exogenous cytidine is not present. Blocking RNA synthesis prior to mating, under conditions in which DNA synthesis either is or is not inhibited, depresses DNA transfer. However, under conditions in which DNA synthesis is inhibited, the blocking of RNA synthesis immediately after mating has commenced had no effect on continued conjugational transfer of DNA. Thus, RNA synthesis is needed to initiate but not to continue conjugational DNA transfer.     

Directed cleavage of ribopolynucleotides with nucleases restricted by multiple modification of substrate.

Simultaneous exhaustive modification of cytidine and uridine residues of rRNA with methoxyamine and sodium metabisulfite renders adjacent phosphodiester bonds resistant to pancreatic and T2 ribonucleases. Another method of T2 RNAase restriction is modification of cytidine with methoxyaminebisulfite followed by modification of guanosine residues with beta-ethoxy-alpha-ketobutyraldehyde. Mild alkaline treatment leads to demodification of uridine and guanosine residues leaving intact modified cytidine residues, thus providing a means of stepwise, directed cleavage of the polynucleotide. The series of combined cleavage procedures and methods of isolation of oligo(C), oligo(G) and oligopyrimidine tracts, as well as the procedure of selective cleavage at uridine residues elaborated in the course of the present studies may serve as a basis for more rational procedures of RNA sequencing.