Base hydrolysis of phosphodiester bonds in pneumococcal polysaccharides

A comprehensive study of the base hydrolysis of all phosphodiester bond-containing capsular polysaccharides of the 23-valent pneumococcal vaccine is described here. Capsular polysaccharides from serotypes 6B, 10A, 17F, 19A, 19F, and 20 contain a phosphodiester bond that connects the repeating units in these polysaccharides (also referred to as backbone phosphodiester bonds), and polysaccharides from serotypes 11A, 15B, 18C, and 23F contain a phosphodiester bond that links a side chain to their repeating units. Molecular weight measurements of the polysaccharides, using high performance size exclusion chromatography with tandem multiangle laser light scattering and refractive index detection, was used to evaluate the kinetics of hydrolysis. The measurement of molecular weight provides a high degree of sensitivity in the case of small extents of reaction, thus allowing reliable measurements of the kinetics over short times. Pseudo-first-order rate constants for these polysaccharides were estimated using a simple model that accounts for the polydispersity of the starting sample. It was found that the relative order of backbone phosphodiester bond instability due to base hydrolysis was 19A > 10A > 19F > 6B > 17F, 20. Degradation of side-chain phosphodiester bonds was not observed, although the high degree of sensitivity in measurements is lost in this case, due to the low contribution of the side chains to the total polysaccharide molecular weight. In comparison with literature data on pneumococcal polysaccharide 6A, 19A was found to be the more labile, and hence appears to be the most labile pneumococcal polysaccharide studied to date. The rate of hydrolysis increased at higher pH and in the presence of divalent cation, but the extent was lower than expected based on similar data on RNA. Finally, the differences in the phosphodiester bond stabilities were analyzed by considering stereochemical factors in these polysaccharides. These results also provide a framework for evaluation of molecular integrity of phosphodiester-bond-containing polysaccharides in different solution conditions.     

The reactivity of phosphomono-and phosphodiester groups in oligonucleotides.

The rate constants were estimated by phosphorus NMR spectroscopy for the reactions of alcohols (Tr-dT, 2-cyanoethanol) in pyridine with the main types of the reactive phosphorylating intermediates formed by treatment of pdT-Ac, pdTpdT-Ac, Tr-dTpdT-Ac, Tr-dTpdTpdT-Ac with 2, 4, 6-triisopropylbenzene-sulfonyl chloride (TPS): 1) B type derivatives with phosphomono ester (PME) group converted to a phosphoryl pyridinium residue; 2) C type derivatives with PME and phosphodiester (PDE) groups converted to trisubstituted pyrophosphate; 3) D type derivatives with PDE groups converted to tetrasubstituted pyrophosphate. The two latter types are partially present as cyclic intramolecular pyrophosphates Ci and Di. The reactivity of the intermediates decrease in the series B greater than Ci approximately Di greater than C approximately D. The Ci derivative of pdTpdT-Ac when obtained in dimethylformamide was found to be rather stable to hydrolysis and could be separated from the other dinucleotide derivatives by ion-exchange chromatography. The Arrhenius parameters of all steps of the conversion of PME group of pdT-Ac to B derivative and of the reaction of TPS with PDE group of dinucleoside phosphate Tr-dTpdT-Ac were measured.     

Biodistribution of phosphodiester and phosphorothioate siRNA

Short interfering RNAs (siRNAs) are valuable tools for analyzing protein function in mammalian cell culture. This success has led to high expectations for in vivo and therapeutic applications. However, the pharmacokinetic properties of siRNA are not known. Here we report the biodistribution of a phosphodiester (PO) siRNA duplex and examine the effect of phosphorothioate (PS) linkages. Our findings indicate that biodistribution of siRNA is similar to that for single-stranded antisense oligonucleotides and offer insights for use of siRNA in vivo.     

Adjuvant effect of liposome-encapsulated natural phosphodiester CpG-DNA

Immunostimulatory CpG-DNA targeting TLR9 is one of the most extensively evaluated vaccine adjuvants. Previously, we found that a particular form of natural phosphodiester bond CpG-DNA (PO-ODN) encapsulated in a phosphatidyl-Β-oleoyl- γ-palmitoyl ethanolamine (DOPE) : cholesterol hemisuccinate (CHEMS) (1 : 1 ratio) complex (Lipoplex(O)) is a potent adjuvant. Complexes containing peptide and Lipoplex(O) are extremely useful for B cell epitope screening and antibody production without carriers. Here, we showed that IL-12 production was increased in bone marrow derived dendritic cells in a CpG sequence-dependent manner when PO-ODN was encapsulated in Lipoplex(O), DOTAP or lipofectamine. However, the effects of Lipoplex(O) surpassed those of PO-ODN encapsulated in DOTAP or lipofectamine and also other various forms of liposome-encapsulated CpG-DNA in terms of potency for protein antigen-specific IgG production and Th1- associated IgG2a production. Therefore, Lipoplex(O) may have a unique potent immunoadjuvant activity which can be useful for various applications involving protein antigens as well as peptides.     

Effective heterogeneous hydrolysis of phosphodiester by pyridine-containing metallopolymers

The copper (II) complex of a simple pyridine- and amide-containing copolymer serves as an effective catalyst for heterogeneous hydrolysis of the prototypical phosphodiester substrate bis(p-nitrophenyl)phosphate at pH 8.0 and 25 °C. The catalysis has a first-order rate constant of k_cat = 8.3 × 10⁻⁶ s⁻¹, corresponding to a catalytic proficiency of 75-thousand folds relative to the uncatalyzed hydrolysis with a rate constant of k₀ = 1.1 × 10⁻¹⁰ s⁻¹ in aqueous buffer solution at pH 8.0. This observation suggests that polymers can be designed to include various functional groups feasible for effective metal-centered catalysis of phosphodiester hydrolysis.     

31P NMR of phospholipid glycerol phosphodiester residues

Saponification of extracted tissue phospholipids yields a set of isolated glycerol 3-phosphoryl phospholipid polar headgroups from which semi-quantitative 31P NMR spectra can be obtained. The resonance signals from these molecules, which frequently have been reported as uncharacterized phosphate signals observed in perchloric acid extracts of tissue, can be used as an aid in the characterization of isolated phospholipids and of tissue phospholipid 31P NMR profiles. 31P NMR chemical-shift values of the resonances at pH 7 in water and relative to 85% phosphoric acid are: glycerol 3-phosphocholine (-0.13 delta), glycerol 3-phosphoethanolamine (0.42 delta), glycerol 3-phospho(monomethyl)ethanolamine (0.29 delta), glycerol 3-phospho(dimethyl)ethanolamine (0.16 delta), glycerol 3-phosphoserine (0.14 delta), glycerol 3-phosphoinositol (-0.07 delta), glycerol 3-phosphoglycerol (0.92 delta), bis(glycerol 3-phospho)glycerol (0.79 delta), serine ethanolamine phosphodiester (-0.46 delta), glycerol 3-phosphate (0.60 delta; 4.29 delta at pH 10) glycerol 2-phosphate (0.15 delta; 3.92 delta at pH 10). In addition, analysis of extracted cancer tissue phospholipid samples yielded a new and uncharacterized polar headgroup fragment with a chemical-shift value of 0.29 delta that is independent of sample pH.     

Hydration of single-stranded phosphodiester and phosphorothioate oligodeoxyribonucleotides.

Infrared spectroscopy was used to identify hydration-sensitive structural differences between single- stranded phosphorothioate (PS) and phosphodiester (PO) oligodeoxyribonucleotides. Spectra were recorded in the mid-infrared region, 500-1800 cm-1, at relative humidities between 0 and 98%; the PS and PO spectra are substantially different. The hydration effects on spectral bands in these single-stranded oligodeoxyribonucleotides is markedly different from such behavior in double- and triple-stranded oligodeoxyribonucleotides. A strong absorption occurs at 656 cm-1 in the phosphorothioate sample which is completely absent from the PO spectra. Gravimetric measurements were carried out on one PS and one PO sample to monitor and confirm hydration. The calculated BET adsorption constants [Brunauer, S., Emmett, RH. and Teller, E. (1938) J. Am. Chem. Soc., 60, 309-319] are 1.2 and 1.4 water molecules per nucleotide in the first hydration layer of PS and PO respectively. While the gravimetric data indicate that the single-stranded oligodeoxyribonucleotides hydrate very similarly to duplex DNA, the mid-infrared conformational marker bands are strikingly different from those observed for duplex DNA. In particular, the Vas of the phosphate group (PO2) at 1222 cm-1 in the single-stranded PO spectra is independent of relative humidity.     

Spin-spin relaxation of the phosphodiester resonance in the 31P NMR spectrum of human brain. The determination of the concentrations of phosphodiester components

The phosphodiester peak in 31P nuclear magnetic resonance spectra of human brain in vivo is often the most prominent feature of the spectrum. We have demonstrated that this resonance exhibits bi-exponential spin-spin relaxation, giving relaxation times of 2 and 10 ms. We interpret this in terms of the two components which make up the peak, bilayer lipids and the small cytosolic phosphates glycerophosphoethanolamine and glycerophosphocholine. Using the relaxation times and the relative peak heights of the two components we have also been able to quantitate the concentration of the bilayer lipids as 20-40 times that of ATP.     

Improvement of in vivo stability of phosphodiester oligonucleotide using anionic liposomes in mice

Antisense phosphodiester oligonucleotides (ODN) are unstable in biological fluids due to nuclease-mediated degradation and therefore cannot be used in most antisense therapeutic applications. We describe here an in vitro and in vivo stabilization of a 15 mer phosphodiester sequence using anionic liposomes. Two formulations have been studied: DOPC/OA/CHOL and DOPE/OA/CHOL (pH-sensitive liposomes). Our in vitro findings reveal the same stabilization effect in mouse plasma for both anionic liposomes. In vivo investigation showed a great protective effect for both formulations after intravenous administration to mice. By contrast with in vitro results, a higher protection of ODN was observed with DOPC/OA/CHOL liposomes compared to the DOPE/OA/CHOL formulation. The latter was degraded in blood (75% of the injected dose at 5 min) probably due to interactions with blood components, and the remaining (25% at 5 min) was distributed mostly to the liver and spleen. DOPC liposomes were remarkably stable in blood and were distributed more slowly to all studied organs (liver, spleen, kidneys and lungs). Intact ODN was still observed in some organs (liver, spleen, lungs), but not in blood, 24 hours after DOPC liposome administration. These results suggest that this antisense strategy using carrier systems may be applicable to the treatment of diseases involving the reticuloendothelial system.     

Accessibility of phosphodiester bonds in the yeast ribosomal 5 S RNA protein complex

The tertiary structure of the protein-associated yeast ribosomal 5 S RNA was examined using ethylnitrosourea reactivity as a probe for phosphodiester bonds. A reduced reactivity was consistently observed in at least nine residues within four distinct regions of the RNA sequence. Seven of these were also observed in three regions of the free RNA molecule while two, A27 and G30, were only present in the ribonucleoprotein complex. The results strongly suggest that the tertiary structure of the free eukaryotic 5 S RNA is largely conserved in the 5 S RNA-protein complex although it appears to be further stabilized in interaction with the ribosomal protein.     

Involvement of the Arg-Asp-His catalytic triad in enzymatic cleavage of the phosphodiester bond

Phosphatidylinositol-specific phospholipase C (PI-PLC) catalyzes the cleavage of the P-O bond in phosphatidylinositol via intramolecular nucleophilic attack of the 2-hydroxyl group of inositol on the phosphorus atom. Our earlier stereochemical and site-directed mutagenesis studies indicated that this reaction proceeds by a mechanism similar to that of RNase A, and that the catalytic site of PI-PLC consists of three major components analogous to those observed in RNase A, the His32 general base, the His82 general acid, and Arg69 acting as a phosphate-activating residue. In addition, His32 is associated with Asp274 in forming a catalytic triad with inositol 2-hydroxyl, and His82 is associated with Asp33 in forming a catalytic diad. The focus of this work is to provide a global view of the mechanism, assess cooperation between various catalytic residues, and determine the origin of enzyme activation by the hydrophobic leaving group. To this end, we have investigated kinetic properties of Arg69, Asp33, and His82 mutants with phosphorothioate substrate analogues which feature leaving groups of varying hydrophobicity and pK(a). Our results indicate that interaction of the nonbridging pro-S oxygen atom of the phosphate group with Arg69 is strongly affected by Asp33, and to a smaller extent by His82. This result in conjunction with those obtained earlier can be rationalized in terms of a novel, dual-function triad comprised of Arg69, Asp33, and His82 residues. The function of this triad is to both activate the phosphate group toward the nucleophilic attack and to protonate the leaving group. In addition, Asp33 and His82 mutants displayed much smaller degrees of activation by the fatty acid-containing leaving group as compared to the wild-type (WT) enzyme, and the level of activation was significantly reduced for substrates featuring the leaving group with low pK(a) values. These results strongly suggest that the assembly of the above three residues into the fully catalytically competent triad is controlled by the hydrophobic interactions of the enzyme with the substrate leaving group.     

Application of oligonucleoside methylphosphonates in the studies on phosphodiester hydrolysis by Serratia endonuclease.

The endonuclease from Serratia marcescens is a non-specific enzyme that cleaves single and double stranded RNA and DNA. It accepts a phosphorylated pentanucleotide as a minimal substrate which is cleaved in the presence of Mg2+ at the second phosphodiester linkage. The present study is aimed at understanding the role of electrostatic and hydrogen bond interactions in phosphodiester hydrolysis. Towards this objective, six pentadeoxyadenylates with single stereoregular methylphosphonate substitution within this minimal substrate (2a-4b) were synthesized following a protocol described here. These modified oligonucleotides were used as substrates for the Serratia nuclease. The enzyme interaction studies revealed that the enzyme failed to hydrolyze any of the methylphosphonate analogues suggesting the importance of negative charge and/or hydrogen bond acceptors in binding and cleavage of its substrate. Based on these results and available site-directed mutagenesis as well as structural data, a model for nucleic acid binding by Serratia nuclease is proposed.     

Simple PbII fluorescent probe based on PbII-catalyzed hydrolysis of phosphodiester

A new fluorescent probe for PbII, p-nitrophenyl 3H-phenoxazin-3-one-7-yl phosphoric acid (NPPA), was designed and synthesized by linking resorufin (serving as a fluorophore and electron acceptor) to p-nitrophenol (serving as a fluorescence quencher and electron donor) through phosphodiester bonds. When NPPA was irradiated with light, intramolecular fluorescence self-quenching took place because of the photoinduced electron transfer from the donor to the acceptor. However, upon the addition of PbII, the phosphate ester bonds in the probe were cleaved and the fluorophore was released, accompanying the retrievement of fluorescence.     

Concerted action at eight phosphodiester bonds by the BcgI restriction endonuclease

The BcgI endonuclease exemplifies a subset of restriction enzymes, the Type IIB class, which make two double-strand breaks (DSBs) at each copy of their recognition sequence, one either side of the site, to excise the sequence from the remainder of the DNA. In this study, we show that BcgI is essentially inactive when bound to a single site and that to cleave a DNA with one copy of its recognition sequence, it has to act in trans, bridging two separate DNA molecules. We also show that BcgI makes the two DSBs at an individual site in a highly concerted manner. Intermediates cut on one side of the site do not accumulate during the course of the reaction: instead, the DNA is converted straight to the final products cut on both sides. On DNA with two sites, BcgI bridges the sites in cis and then generally proceeds to cut both strands on both sides of both sites without leaving the DNA. The BcgI restriction enzyme can thus excise two DNA segments together, by cleaving eight phosphodiester bonds within a single-DNA binding event.     

Biosynthesis of the phosphodiester bond in coenzyme F(420) in the methanoarchaea

The biochemical route for the formation of the phosphodiester bond in coenzyme F(420), one of the methanogenic coenzymes, has been established in the methanoarchaea Methanosarcina thermophila and Methanococcus jannaschii. The first step in the formation of this portion of the F(420) structure is the GTP-dependent phosphorylation of L-lactate to 2-phospho-L-lactate and GDP. The 2-phospho-L-lactate represents a new natural product that was chemically identified in Methanobacterium thermoautotrophicum, M. thermophila, and Mc. jannaschii. Incubation of cell extracts of both M. thermophila and Mc. jannaschii with [hydroxy-(18)O, carboxyl-(18)O(2)]lactate and GTP produced 2-phospho-L-lactate with the same (18)O distribution as found in both the starting lactate and the lactate recovered from the incubation. These results indicate that the carboxyl oxygens are not involved in the phosphorylation reaction. Incubation of Sephadex G-25 purified cell extracts of M. thermophila or Mc. jannaschii with 7,8-didemethyl-8-hydroxy-5-deazariboflavin (Fo), 2-phospho-L-lactate, and GTP or ATP lead to the formation of F(420)-0 (F(420) with no glutamic acids). This transformation was shown to involve two steps: (i) the GTP- or ATP-dependent activation of 2-phospho-L-lactate to either lactyl(2)diphospho-(5')guanosine (LPPG) or lactyl(2)diphospho-(5')adenosine (LPPA) and (ii) the reaction of the resulting LPPG or LPPA with Fo to form F(420)-0 with release of GMP or AMP. Attempts to identify LPPG or LPPA intermediates by incubation of cell extracts with L-[U-(14)C]lactate, [U-(14)C]2-phospho-L-lactate, or [8-(3)H]GTP were not successful owing to the instability of these compounds toward hydrolysis. Synthetically prepared LPPG and LPPA had half-lives of 10 min at 50 degrees C (at pH 7.0) and decomposed into GMP or AMP and 2-phospho-L-lactate via cyclic 2-phospho-L-lactate. No evidence for the functioning of the cyclic 2-phospho-L-lactate in the in vitro biosynthesis could be demonstrated. Incubation of cell extracts of M. thermophila or Mc. jannaschii with either LPPG or LPPA and Fo generated F(420)-0. In summary, this study demonstrates that the formation of the phosphodiester bond in coenzyme F(420) follows a reaction scheme like that found in one of the steps of the DNA ligase reaction and in the biosynthesis of coenzyme B(12) and phospholipids.