The Terminal Phosphate in d(pGpG) Reduces Self-Association

Abstract

An investigation of the self-association behavior of 2′-deoxy[5′-phosphate-guanylyl-(3′-5′)-guanosine] (d(pGpG)) in the presence of Na⁺ and K⁺ ions has been carried out by ¹H and ³¹PNMR and FTIR spectroscopy. A comparison has been made of the self-association behavior of d(pGpG) with that of the related dinucleotide d(GpG), which has been shown to form extended structures based on stacked G-tetrads. Chemically, d(pGpG) monomer differs from d(GpG) only by the addition of a phosphate at the 5′-OH of the sugar residue. It was found that the addition of the second phosphate interferes with self-association. A suitable counterion is all that is required by d(GpG) to induce the formation of large super structures, but for d(pGpG) a large excess of salt is needed to produce the same effect. However, once self-association occurs, d(pGpG) forms similar structures to d(GpG) and has nearly the same properties. For both compounds, the K⁺ ion induces a more stable structure than the Na⁺ ion. The ³¹P NMR chemical shift ranges of d(pGpG) were consistent with the reported data for a phosphodiester and terminal phosphate. The small change in the chemical shift of the terminal phosphate with increasing temperature suggests that no major change in the terminal phosphate conformation occurred upon self-association. It was concluded that the terminal phosphate did not result in steric hindrance to self-association, but that interference to self-association was due to electrostatic repulsion effects.     

Non-Watson-Crick structures in oligodeoxynucleotides: self-association of d(TpCpGpA) stabilized at acidic pH

The 1H NMR spectrum of the tetradeoxynucleotide d(TpCpGpA) was examined as a function of temperature, pH, and concentration. At pH 7 and above the solution conformation for this oligodeoxynucleotide appears to be a mixture of random coil and Watson-Crick duplex. At 25 degrees C, a pH titration of d(TpCpGpA) shows that distinct conformational changes occur as the pH is lowered below 7.0. These conformational changes are reversible upon readjusting the pH to neutrality, indicating the presence of a pH-dependent set of conformational equilibria. At 25 degrees C, the various conformational states in the mixture are in rapid exchange on the NMR time scale. Examination of the titration curve shows the presence of distinct conformational states at pH greater than 7, and between pH 4 and pH 5. At pH less than 4, a third conformational state is present. When the pH titration is repeated at 5 degrees C, the conformational equilibria are in slow exchange on the NMR time scale; distinct signals from each conformational state are observable. The stable conformational state present between pH 4 and pH 5 represents an ordered conformation of d(TpCpGpA) which dissociates to a less ordered structure upon raising the temperature. This ordered conformation does not result from an intramolecular rearrangement, as is shown by by spectra obtained by varying oligodeoxynucleotide concentration at constant pH. The ordered conformation differs from the Watson-Crick helix, as is shown from nuclear Overhauser enhancement experiments, as well as chemical shift data. An ordered conformation for d(TpCpGpA) was previously reported [Reid, D. G., Salisbury, S. A., Brown, T., & Williams, D. H. (1985) Biochemistry 24, 4325-4332].(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular structure of the complex formed between the anticancer drug cisplatin and d(pGpG): C222(1) crystal form

The three dimensional molecular structure of the adduct formed between the anticancer drug cisplatin and a DNA dinucleotide d(pGpG) has been determined by x-ray diffraction analysis at 1.37 A resolution and refined to a final R-factor of 0.11. This structure, solved by using data from a previously reported crystal form in the space group C222(1), resembles that found in the space group P2(1)2(1)2 (Sherman, et al., Science, 230, 412-417, 1985; ibid, J. Amer. Chem. Soc. 110, 7368-7381, 1988). In both structures, four crystallographically independent cis-[Pt(NH3)2(d(pGpG]] molecules aggregate into a tetrameric cluster that is stabilized by a large number of intermolecular hydrogen bonds and base-base stacking interactions. In each molecule, the platinum atom is coordinated to the N7 atoms of two guanine bases arranged in a head-to-head orientation, resulting in a large dihedral angle between the guanines. Intermolecular guanine-guanine base pairings between different intrastrand crosslinked molecules are used extensively in the crystal lattice.     

Formation of d(-)-1,2-propanediol and d(-)-lactate from glucose by Clostridium sphenoides under phosphate limitation

Clostridium sphenoides was grown on glucose in a phosphate-limited medium. Below 80 M phosphate two new products were formed in addition to ethanol, acetate, H₂ and CO₂: d(-)-1,2-propanediol and d(-)-lactate. These compounds were apparently synthesized via the methylglyoxal by-pass. The activity of the enzymes involvedmethylglyoxal synthase, methylglyoxal reductase, 1,2-propanediol dehydrogenase and glyoxalase-could be demonstrated in cell extracts of C. sphenoides. The formation of 1,2-propanediol from methylglyoxal proceeded via lactaldehyde. The enzyme methylgloxal synthase was inhibited by phosphate. Clostridium glycolicum, C. nexile, C. cellobioparum, C. oroticum and C. indolis did not produce propanediol under the condition of phosphate limitation. The latter two species, however, formed d(-)-lactate.Dedicated to Prof. Dr. G. Drews on the occasion of his 60th birthday     

The liver-specific human alpha(1)-microglobulin/bikunin precursor (AMBP) is capable of self-association

alpha-1-Microglobulin (A1M) and bikunin are two plasma glycoproteins encoded by an alpha-1-microglobulin/bikunin precursor (AMBP) gene. Despite their lack of any structural or functional relationship, both A1M and bikunin originate from AMBP cleavage by a furin-like protease that releases the two mature molecules. The AMBP gene maintains a tight control over its expression by a unique enhancer, which is controlled by several hepatocyte-enriched nuclear factors; however, the mechanisms of regulation of the intracellular levels of the AMBP protein are currently unknown. We report the ability of the AMBP protein to self-associate and form a dimer in a yeast environment using the yeast two-hybrid system and an in vitro dimerization assay. We also show that the A1M protein binds to its precursor protein, AMBP, whereas bikunin does not. This observation warrants further investigations for a dimerization-dependent intracellular control that AMBP may be involved in. The relevance of AMBP dimerization and its possible biological significance are postulated.     

B--Z conformational transition in d(CGCGCGTTAATT), d(CGCGCGTTAA) and d(CGCGCGTT)

Conformational studies on three DNA-oligomers (d(CGCGCGTTAATT), d(CGCGTTAA) and d(CGCGCGTT) in solution by circular dichroism spectroscopy are reported. In low salt solution, all three DNA oligomers exhibit a characteristic B-conformation. However, under the influence of high salt concentration i.e. 5M NaCl, the octamer d(CGCGCGTT) exhibits 'A' conformation whereas the decamer and dodecamer retain B-conformation. On addition of millimolar amount of NiCl2 to the 5M NaCl, solution of oligodeoxynucleotides a B-Z transition is observed in octamer, decamer and dodecamer. However, NiCl2 titrations show that mid point of transition for dodecamer is at 2.25 mM, for decamer is at 13 mM NiCl2 and for octamer is 17 mM at NiCl2. In 60% alcohol all three oligonucleotides remain in the B-conformation. The melting temperatures of oligonucleotides at various salt concentration are also reported. Thermodynamic parameters calculated by melting profile using a two state model show that dodecamer and decamer are most stable in their 5M NaCl, B-form. However, octamer is more stable in its Z form than that of its 'A' form.     

The molecular structure of Okazaki fragment r(CGCA)d(AAAAAGCG):d(CGCTTTTTTGCG) in solution

The hetero duplex molecule, r(CGCA)d(AAAAAGCG):d(CGCTTTTTTGCG) which corresponds to Okazaki fragment was synthesized and its molecular structure has been analyzed by NMR study. The RNA strand of RNA-DNA hybrid region adopts A-form and DNA strand of the same region deviates from the standard B-form. The conformation of DNA-DNA duplex segment belongs to B-form. The hybrid-DNA duplex junction shows a structural discontinuities, A-B junction. The same conformational characteristic of oligo(dA): oligo(dT) tract as that of DNA oligomer which has same base sequence has been observed.     

The dependence of isotopically exchangeable phosphate (L-value) on phosphate uptake

Summary L-values were determined using clover and ryegrass, grown either separately or together, in soil or soil/sand media. Where the two species were grown in the same pot, there was no interspecific effect on L-value. However, as the experiment progressed L-values increased and clover and ryegrass grown separately gave different values. The increases can be explained by P uptake, single regressions of L-value on phosphate uptake accounting for 86 and 88 per cent of the variations in L-value on the two soils used, with little improvement for treating the two crops separately. The most likely explanation for the observation is that the phosphate stress placed on the soil system caused mobilization of previously non-labile P by the dissolution of sparingly soluble phosphate compounds.     

Guanine-06 methylation reduces the reactivity of d(GpG) towards platinum complexes.

6-methylated guanine dinucleotides were used to study the influence of hydrogen bonding on the specific binding of the antitumor drug cDDP, cis-PtCl2(NH3)2, to DNA. In this interaction, the guanine-06 site appears to be important in explaining the preference for a pGpG-N7(1),N7(2) chelate, which results from H-bridge formation with the ammine ligand of cDDP. Guanine-06 methylated dinucleotides and the nonmodified dinucleotides were reacted with [Pt(dien)Cl]+, cis-PtCl2(NH3)2, and cis-[Pt(NH3)2(H2O)2]2+ and the reaction products were characterized by 1H NMR using pH titrations. Methylation at guanine-06 clearly reduces the preference for the guanine. In competition experiments monitored by NMR and experiments using UV spectrophotometry a decreasing reactivity towards [Pt(dien)(H2O)]2+ and cis-[Pt(NH3)2(H2O)2]2+ was found, in the order of d(GpG) greater than d(GomepG) greater than d(GpGome) greater than d(GomepGome). The difference in reactivity between 5' guanine methylation and 3' guanine methylation is ascribed to differences in the H-bond formation with the backbone phosphate. The resulting reduced stacking of the bases in both modified dinucleotides, compared to the bases in d(GpG), results in a preference for the 3' guanine over 5'.     

The polysome as a terminal for the creatine phosphate energy shuttle

The role of the creatine phosphate shuttle in the energetics of muscle protein synthesis in isolated polysomes, from rat hindlimb muscle, was studied. Triton X-100-treated polysomes, following their centrifugation through a 1 M sucrose gradient, contained 38 mU/mg RNA of bound creatine kinase. In the presence of pH 5 enzyme (obtained from rat liver), 0.5 mM ATP, and 1 microM GTP, amino acid (leucine) incorporation by polysomes in the presence of 8 mM creatine phosphate was twice that in the presence of an exogenous ATP regenerating system of 10 mM phospho(enol)pyruvate and 10 U/ml pyruvate kinase. Since added creatine kinase had no effect on incorporation supported by creatine phosphate it is clear that endogenous creatine kinase allows sufficient regeneration of ATP. These data also suggest that nucleoside diphosphokinase must have been associated with the polysome for phosphate was transferred to GTP from [33P]creatine phosphate, and the specific activities of ATP and GTP increased at equal rates, reaching the specific activity of creatine phosphate at 8 min. We conclude that skeletal muscle polysomes have bound creatine kinase activity and they act as terminals for the creatine phosphate energy shuttle. Creatine phosphate regenerates GTP, probably through an intermediate reaction catalyzed by nucleoside diphosphokinase. This provided an added support for the hypothesis of compartmentation of enzymes and substrates and that the transport form of energy between the mitochondria and energy utilizing sites in muscle is creatine phosphate rather than ATP, which extends the general role of the creatine phosphate energy shuttle.     

The Solution Structure of [d(CGC)r(amamam)d(TTTGCG)]2

The solution structure and hydration of a DNARNA hybrid chimeric duplex [d(CGC)r(a_ma_ma_m)d(TTTGCG)]₂ in which the RNA adenines were substituted by 2-O-methylated riboadenines was determined using two-dimensional NMR, simulated annealing, and restrained molecular dynamics. Only DNA residue 7T in the 2-OMe-RNA DNA junction adopted an O4-endo sugar conformation, while the other DNA residues including 3C in the DNA 2-OMe-RNA junction, adopted C1-exo or C2-endo conformations. The observed NOE intensity of 2-O-methyl group to H1 proton of 4a_m at the DNA 2-OMe-RNA junction is much weaker than those of 5a_m and 6a_m. The 2-O-methyl group of 4a_m was found to orient towards the minor groove in the trans domain while the 2-O- methyl groups of 5a_m and 6a_m were found to be in the gauche (+) domain. In contrast to the long-lived water molecules found close to the RNA adenine H2 and H1 protons and the methyl group of 7T in the RNA-DNA junction of [d(CGC)r(aaa)d(TTTGCG)]₂, there were no long-lived water molecules found in [d(CGC)r(a_ma_ma_m)d(TTTGCG)]₂. This is probably due to the hydrophobic enviroment created by the 2-O-methylated riboadenines in the minor groove or due to the wider minor groove width in the middle of the structure. In addition, the 2-O-methylation of riboadenines in pure chimeric duplex increses its melting temperature from 48.5°C to 51.9°C. The characteristic structural features and hydration patterns of this chimeric duplex provide a molecular basis for further therapeutic applications of DNARNA hybrid and chimeric duplexes with 2-modified RNA residues.     

High external phosphate (Pi) increases sodium ion uptake and reduces salt tolerance of 'Pi-tolerant' soybean

Previous studies on the interaction between environmental inorganic phosphate (Pi) and salinity stress using soybean cultivars sensitive to high external Pi had two limitations: (1) the phenotype was dominated by overaccumulation of phosphorus (P); and (2) no detailed analysis was performed for sodium ion uptake. In this study, we focused on the effects of high external Pi on the sodium ion uptake in 'Pi-tolerant' soybean cultivars. The P accumulation in Pi-tolerant soybean Union was much lower [9.0 mg g⁻¹ dry weight (DW); contrasting to 38–76 mg g⁻¹ DW in the 'Pi-sensitive' soybean cultivars]. At in planta level, high level of external Pi significantly ( P  < 0.001) increased net sodium ion uptake and aggravated salinity stress symptoms. The effects of high external Pi diminished when de-rooted plants were used, suggesting that root is the primary organ interacting with Pi in the growth medium. Two-cell models, including soybean suspension cells and the tobacco Bright Yellow-2 cell line, were also employed to study the effects of high external Pi at the cellular level. Consistent to in planta results, high external Pi uplifted cellular sodium ion uptake and reduced cell viability under salinity stress. Gene expression analyses further showed that HPi (2 m M Pi supplements; excessive level of Pi) could reduce the fold of induction of GmSOS1 and GmCNGC under salinity stress, suggesting that they may be possible molecular targets involved in the interaction between high external Pi and Na⁺ uptake.     

Molecular-Mechanical studies of the mismatched base analogs of d(CGCGAATTCGCG)2:d(CGTGAATTCGCG)2, d(CGAGAATTCGCG)2, d(CGCGAATTCACG)2, d(CGCGAATTCTCG)2, and d(CGCAGAATTCGCG)·d(CGCGAATTCGCG)

Molecular-mechanical simulations have been carried out on “mismatched base” analogs of the DNA double-helical structure d(CGCGAATTCGCG)₂, in which the base pairs CG at the 3 and 10 positions have been replaced by CA, AG, TC, and TG base pairs, as well as an insertion analog in which an extra adenine has been incorporated into one strand of the above structure between bases 3 and 4. The results of these simulations (calculated relative stabilities, structures, and nmr ring-current shifts) have been compared with calorimetric and nmr data. The calculated relative stabilities of the double-helical parent dodecamer and the various “wobble” base pairs qualitatively correlate with the experimental melting temperatures. The base-pairing structure for the GT wobble pair is in agreement with that previously determined from nmr experiments. For the GA base pair, the structure with both bases anti has a slightly more favorable energy from base pairing and stacking than a structure with non-Watson-Crick H-bonding with adenine syn, in agreement with nmr experiments. The CA wobble base is calculated to favor an adenine 6NH₂ …? cytosine N3 H-bond over cytosine 4NH₂ …? adenine N1, again, in agreement with nmr experiments. There is no definitive experimental data on the TC base pair, but the existence of (somewhat long and weak) H-bonds involving cytosine 4NH₂ …? thymine 4CO and cytosine N3 …? thymine HN3 seems reasonable. We find a structure in which the extra adenine base of the insertion analogs sits “inside” the double helix.     

The phylogeny of orthoretroviral long terminal repeats (LTRs)

LTRs are sequence elements in retroviruses and retrotransposons which are difficult to align due to their variability. One way of handling such cases is to use Hidden Markov Models (HMMs). In this work HMMs of LTRs were constructed for three groups of orthoretroviruses: the betaretroviruslike human MMTV-like (HML) endogenous retroviruses, the lentiviruses, including HIV, and gammaretroviruslike human endogenous retroviruses (HERVs). The HMM-generated LTR alignments and the phylogenetic trees constructed from them were compared with trees based on alignments of the pol gene at the nucleic acid level. The majority of branches in the LTR and pol based trees had the same order for the three retroviral genera, showing that HMM methods are successful in aligning and constructing phylogenies of LTRs. The HML LTR tree deviated somewhat from the pol tree for the groups HML3, HML7 and HML6. Among the gammaretroviruslike proviruses, the exogenous Mouse Leukemia Virus (MLV) was highly related to HERV-T in the pol based tree, but not in the LTR based tree. Aside from these differences, the similarity between the trees indicates that LTRs and pol coevolved in a largely monophyletic way.     

The octamers d(CGCGCGCG) and d(CGCATGCG) both crystallize as Z-DNA in the same hexagonal lattice

Both (dC-dG)₄ and d(CGCATGCG) crystallize in hexagonal lattices and their three-dimensional structure has been solved by x-ray diffraction analysis. Both molecules are found to form Z-DNA, although the fine details of the structure cannot be visualized due to the statistical disordering of the molecules along the c-axis, which is brought about by the symmetry constraints of the space group. This represents the first time in which the unmodified dinucleotide sequences CpAp and TpGp have been found to form Z-DNA in a crystalline lattice.     

Leucine-regulated self-association of leucine-responsive regulatory protein (Lrp) from Escherichia coli

Lrp is a global regulatory protein in Escherichia coli that activates expression of more than a dozen operons and represses expression of another dozen. For some operons, exogenous leucine reduces the extent of Lrp action, for others it potentiates the effect of Lrp, and for yet other operons it has no effect. In an effort to understand how leucine affects Lrp-mediated expression, we examined Lrp self-association and the effect of leucine on self-association using light scattering, chemical cross-linking, and analytical ultracentrifugation. The following results were obtained. (i) Lrp self-associates to a hexadecamer and octamer with the predominant species being hexadecamer at microM concentrations. (ii) Lrp undergoes a leucine-induced dissociation of hexadecamer to octamer. (iii) A mutant Lrp lacking 11 amino acid residues at the C terminus does not form higher-order oligomers, suggesting that the C terminus is involved in subunit association. (iv) At nM concentrations, Lrp dissociates to a dimer. It is proposed that leucine regulates the equilibrium between Lrp oligomers and thus Lrp occupancy of sites within different operons, leading to diverse regulatory patterns.     

DNA-drug interactions. The crystal structures of d(TGTACA) and d(TGATCA) complexed with daunomycin

The anticancer drug daunomycin has been co-crystallized with the hexanucleotide duplex sequences d(TGTACA) and d(TGATCA) and single crystal X-ray diffraction studies of these two complexes have been carried out. Structure solution of the d(TGTACA) and d(TGATCA) complexes to 1.6 and 1.7 Angstrom resolution, respectively, shows two daunomycin molecules bound to the DNA hexamer. Binding occurs via intercalation of the drug chromophore at the d(TpG) step, and hydrogen bonding interactions involving the drug, DNA and solvent molecules. The daunomycin sugar is located in the minor groove of the DNA hexamer and is stabilized by hydrogen bonds between the amino group of the sugar and functional groups on the floor of the groove. The amino sugar of the d(TGATCA) duplex interacts directly with the DNA sequence, while in the d(TGTACA) duplex, the interaction is via solvent molecules. Two other complexes d(CGTACG)-daunomycin and d(CGATCG)-daunomycin have previously been structurally characterized. Comparison of the four structures with daunomycin bound to the triplet sequences 5'TGT, 5'TGA, 5'CGT and 5'CGA reveals changes in the conformation of both the DNA hexamer and the daunomycin upon complexation, as well as the hydrogen bonding and van der Waals' interactions.     

The purine-rich trinucleotide repeat sequences d(CAG)15 and d(GAC)15 form hairpins.

The structures of single-stranded (ss) oligonucleotides containing (CAG)15 [ss(CAG)15] or (GAC)15 [ss(GAC)15] were examined. At 10 degrees C, the electrophoretic mobilites of the two DNAs were similar to ss(CTG)15, a DNA that forms a hairpin containing base paired and/or stacked thymines. At 37 degrees C in 50 mM NaCl, single-strand-specific P1 nuclease cleaved the G33-G36 phosphodiesters of ss(GAC)15, and the G32-A34, G35-C36 phosphodiesters of ss(CAG)15 (where the loop apex of both DNAs = A34). Electrophoretic mobility melting profiles indicated that the melting temperature (Tm) of ss(CAG)15 in low (approximately 1 mM Na+) ionic strength was 38 degrees C. In contrast, the Tm of ss(GAC)15 was 49 degrees C, a value similar to the Tm of ss(CTG)15. These results provide evidence that ss(GAC)15 and ss(CAG)15 form similar, but distinguishable hairpin structures.