Enzymatic synthesis of hypermodified DNA polymers for sequence-specific display of four different hydrophobic groups.

A set of modified 2'-deoxyribonucleoside triphosphates (dNTPs) bearing a linear or branched alkane, indole or phenyl group linked through ethynyl or alkyl spacer were synthesized and used as substrates for polymerase synthesis of hypermodified DNA by primer extension (PEX). Using the alkyl-linked dNTPs, the polymerase synthesized up to 22-mer fully modified oligonucleotide (ON), whereas using the ethynyl-linked dNTPs, the enzyme was able to synthesize even long sequences of >100 modified nucleotides in a row. In PCR, the combinations of all four modified dNTPs showed only linear amplification. Asymmetric PCR or PEX with separation or digestion of the template strand can be used for synthesis of hypermodified single-stranded ONs, which are monodispersed polymers displaying four different substituents on DNA backbone in sequence-specific manner. The fully modified ONs hybridized with complementary strands and modified DNA duplexes were found to exist in B-type conformation (B- or C-DNA) according to CD spectral analysis. The modified DNA can be replicated with high fidelity to natural DNA through PCR and sequenced. Therefore, this approach has a promising potential in generation and selection of hypermodified aptamers and other functional polymers.

Adaptation of Bacillus subtilis to Life at Extreme Potassium Limitation.

Potassium is the most abundant metal ion in every living cell. This ion is essential due to its requirement for the activity of the ribosome and many enzymes but also because of its role in buffering the negative charge of nucleic acids. As the external concentrations of potassium are usually low, efficient uptake and intracellular enrichment of the ion is necessary. The Gram-positive bacterium Bacillus subtilis possesses three transporters for potassium, KtrAB, KtrCD, and the recently discovered KimA. In the absence of the high-affinity transporters KtrAB and KimA, the bacteria were unable to grow at low potassium concentrations. However, we observed the appearance of suppressor mutants that were able to overcome the potassium limitation. All these suppressor mutations affected amino acid metabolism, particularly arginine biosynthesis. In the mutants, the intracellular levels of ornithine, citrulline, and arginine were strongly increased, suggesting that these amino acids can partially substitute for potassium. This was confirmed by the observation that the supplementation with positively charged amino acids allows growth of B. subtilis even at the extreme potassium limitation that the bacteria experience if no potassium is added to the medium. In addition, a second class of suppressor mutations allowed growth at extreme potassium limitation. These mutations result in increased expression of KtrAB, the potassium transporter with the highest affinity and therefore allow the acquisition and accumulation of the smallest amounts of potassium ions from the environment.IMPORTANCE Potassium is essential for every living cell as it is required for the activity for many enzymes and for maintaining the intracellular pH by buffering the negative charge of the nucleic acids. We have studied the adaptation of the soil bacterium Bacillus subtilis to life at low potassium concentrations. If the major high-affinity transporters are missing, the bacteria are unable to grow unless they acquire mutations that result in the accumulation of positively charged amino acids such as ornithine, citrulline, and arginine. Supplementation of the medium with these amino acids rescued growth even in the absence of externally added potassium. Moreover, these growth conditions, which the bacteria experience as an extreme potassium limitation, can be overcome by the acquisition of mutations that result in increased expression of the high-affinity potassium transporter KtrAB. Our results indicate that positively charged amino acids can partially take over the function of potassium.

New highly active antiplatelet agents with dual specificity for platelet P2Y1 and P2Y12 adenosine diphosphate receptors.

Currently approved platelet adenosine diphosphate (ADP) receptor antagonists target only the platelet P2Y12 receptor. Moreover, especially in patients with acute coronary syndromes, there is a strong need for rapidly acting and reversible antiplatelet agents in order to minimize the risk of thrombotic events and bleeding complications. In this study, a series of new P(1),P(4)-di(adenosine-5') tetraphosphate (Ap4A) derivatives with modifications in the base and in the tetraphosphate chain were synthesized and evaluated with respect to their effects on platelet aggregation and function of the platelet P2Y1, P2Y12, and P2X1 receptors. The resulting structure-activity relationships were used to design Ap4A analogs which inhibit human platelet aggregation by simultaneously antagonizing both P2Y1 and P2Y12 platelet receptors. Unlike Ap4A, the analogs do not activate platelet P2X1 receptors. Furthermore, the new compounds exhibit fast onset and offset of action and are significantly more stable than Ap4A to degradation in plasma, thus presenting a new promising class of antiplatelet agents.

ABCC6 prevents ectopic mineralization seen in pseudoxanthoma elasticum by inducing cellular nucleotide release.

Pseudoxanthoma elasticum (PXE) is an autosomal recessive disease characterized by progressive ectopic mineralization of the skin, eyes, and arteries, for which no effective treatment exists. PXE is caused by inactivating mutations in the gene encoding ATP-binding cassette sub-family C member 6 (ABCC6), an ATP-dependent efflux transporter present mainly in the liver. Abcc6(-/-) mice have been instrumental in demonstrating that PXE is a metabolic disease caused by the absence of an unknown factor in the circulation, the presence of which depends on ABCC6 in the liver. Why absence of this factor results in PXE has remained a mystery. Here we report that medium from HEK293 cells overexpressing either human or rat ABCC6 potently inhibits mineralization in vitro, whereas medium from HEK293 control cells does not. Untargeted metabolomics revealed that cells expressing ABCC6 excrete large amounts of nucleoside triphosphates, even though ABCC6 itself does not transport nucleoside triphosphates. Extracellularly, ectonucleotidases hydrolyze the excreted nucleoside triphosphates to nucleoside monophosphates and inorganic pyrophosphate (PPi), a strong inhibitor of mineralization that plays a pivotal role in several mineralization disorders similar to PXE. The in vivo relevance of our data are demonstrated in Abcc6(-/-) mice, which had plasma PPi levels <40% of those found in WT mice. This study provides insight into how ABCC6 affects PXE. Our data indicate that the factor that normally prevents PXE is PPi, which is provided to the circulation in the form of nucleoside triphosphates via an as-yet unidentified but ABCC6-dependent mechanism.

Structures of yeast Apa2 reveal catalytic insights into a canonical AP4A phosphorylase of the histidine triad superfamily.

The homeostasis of intracellular diadenosine 5',5″'-P(1),P(4)-tetraphosphate (Ap4A) in the yeast Saccharomyces cerevisiae is maintained by two 60% sequence-identical paralogs of Ap4A phosphorylases (Apa1 and Apa2). Enzymatic assays show that, compared to Apa1, Apa2 has a relatively higher phosphorylase activity towards Ap3A (5',5″'-P(1),P(3)-tetraphosphate), Ap4A, and Ap5A (5',5″'-P(1),P(5)-tetraphosphate), and Ap4A is the favorable substrate for both enzymes. To decipher the catalytic insights, we determined the crystal structures of Apa2 in the apo-, AMP-, and Ap4A-complexed forms at 2.30, 2.80, and 2.70Å resolution, respectively. Apa2 is an α/ß protein with a core domain of a twisted eight-stranded antiparallel ß-sheet flanked by several α-helices, similar to the galactose-1-phosphate uridylyltransferase (GalT) members of the histidine triad (HIT) superfamily. However, a unique auxiliary domain enables an individual Apa2 monomer to possess an intact substrate-binding cleft, which is distinct from previously reported dimeric GalT proteins. This cleft is perfectly complementary to the favorable substrate Ap4A, the AMP and ATP moieties of which are perpendicular to each other, leaving the α-phosphate group exposed at the sharp turn against the catalytic residue His161. Structural comparisons combined with site-directed mutagenesis and activity assays enable us to define the key residues for catalysis. Furthermore, multiple-sequence alignment reveals that Apa2 and homologs represent canonical Ap4A phosphorylases, which could be grouped as a unique branch in the GalT family.

Methylation of the ESR1 CpG island in the colorectal mucosa is an 'all or nothing' process in healthy human colon, and is accelerated by dietary folate supplementation in the mouse.

ESR1 is frequently silenced by CGI (CpG island) methylation, both in human colorectal tumours and, in an age-dependent manner, in healthy mucosa. It is not clear, however, whether methylation of individual cytosines occurs randomly within the epithelial genome, or preferentially within individual cells as an 'all-or-nothing' phenomenon. CGI methylation can be quantified in human DNA residues recovered from faecal samples. We used bisulphite genomic sequencing of human DNA from this source and from a colorectal cancer cell line (SW48) to show that the ESR1 CGI is methylated in an allele-specific manner. This provides support for the 'all or none' mechanism for methylation of this gene, and shows how age-dependent methylation of the ESR1 CGI leads rapidly to silencing of the gene within the cells, and hence the colonic crypt within which it occurs. Preliminary studies with a rodent model suggest the rate of age-dependent methylation of ESR1 is modifiable by dietary folate.

A mechanism of AZT resistance: an increase in nucleotide-dependent primer unblocking by mutant HIV-1 reverse transcriptase.

Mutations in HIV-1 reverse transcriptase (RT) give rise to 3'-azido-3'-deoxythymidine (AZT) resistance by a mechanism that has not been previously reproduced in vitro. We show that mutant RT has increased ability to remove AZTMP from blocked primers through a nucleotide-dependent reaction, producing dinucleoside polyphosphate and extendible primer. In the presence of physiological concentrations of ATP, mutant RT extended 12% to 15% of primers past multiple AZTMP termination sites versus less than 0.5% for wild type. Although mutant RT also unblocked ddAMP-terminated primers more efficiently than wild-type RT, the removal of ddAMP was effectively inhibited by the next complementary dNTP (IC50 approximately equal to 12 microM). In contrast, the removal of AZTMP was not inhibited by dNTPs except at nonphysiological concentrations (IC50 > 200 microM).

Stereochemical retention of the configuration in the action of Fhit on phosphorus-chiral substrates.

Fhit is the protein product of FHIT, a candidate human tumor suppressor gene. Fhit catalyzes the hydrolysis of diadenosine triphosphate (Ap3A) to AMP and ADP. Fhit is here shown to catalyze the hydrolysis in H218O with production of adenosine 5'-[18O]phosphate and ADP, proving that the substitution of water is at Palpha and not at Pbeta. The chain fold of Fhit is similar to that of galactose-1-phosphate uridylyltransferase, which functions by a double-displacement mechanism through the formation of a covalent nucleotidyl-enzyme intermediate and overall retention of configuration at Palpha. The active site of Fhit contains a histidine motif that is reminiscent of the HPH motif in galactose-1-phosphate uridylyltransferases, in which the first histidine residue serves as the nucleophilic catalyst to which the nucleotidyl group is bonded covalently in the covalent intermediate. In this work, the Fhit-catalyzed cleavage of (RP)- and (SP)-gamma-(m-nitrobenzyl) adenosine 5'-O-1-thiotriphosphate (mNBATPalphaS) in H218O to adenosine 5'-[18O]thiophosphate is shown to proceed with overall retention of configuration at phosphorus. gamma-(m-Nitrobenzyl) adenosine 5'-O-triphosphate (mNBATP) is approximately as good a substrate for Fhit as Ap3A, and both (RP)- and (SP)-mNBATPalphaS are substrates that react at about 0.5% of the rate of Ap3A. The stereochemical evidence indicates that hydrolysis by Fhit proceeds by a double-displacement mechanism, presumably through a covalent AMP-enzyme intermediate.

The response of peritoneal macrophages after implantation of several ceramics as measured by the change of ectoenzyme activity.

The bioactive calcium phosphate ceramics with various calcium: phosphorus ratios: Ca/P = 1.67 (hydroxyapatite, HA), Ca/P = 1.6 and Ca/P = 1.5 (tricalcium phosphate, beta-TCP), the bioinert aluminium oxide ceramic (Al2O3) and the toxic calcium oxide ceramic (CaO) have been investigated with respect to their ability to activate peritoneal macrophages of NMRI-mice and with respect to their influence on the extracellular nucleotide degradation of these macrophages. Two weeks after the intraperitoneal injection of a suspension of ceramic particles in an isotone salt solution (phosphate-buffered saline = PBS), we observed that the peritoneal macrophages were only slightly activated into the responsive state, independent of the type of ceramic. 5'Nucleotidase (5'N) ectoenzyme hydrolyses adenosine monophosphate (AMP) and a decrease of its activity is a general biochemical marker of activated macrophages. This ectoenzyme activity was slightly reduced after ceramic implantation. The lacking rise of the extracellular diadenosine tetraphosphate (Ap4A)-catabolism by the macrophage ectoenzyme alkaline phosphodiesterase I (APD) demonstrated that the peritoneal macrophages did not completely reach the responsive state. After the implantation of calcium phosphate ceramics the extracellular adenosine triphosphate (ATP)-reduction was slightly diminished. After the implantation of tricalcium phosphate ceramic about 30% more peritoneal exsudate cells (PEC) were obtained from the peritoneal cavity than after injections of pure PBS (used as non-inflammatory control). Similar to the phenomena following the injection of thioglycollate (Tg, inflammation producing control agent) a slightly but not significantly increased proportion of pseudopodia-building cells was observed after the implantation of the ceramic with Ca/P = 1.6.

A component of the transcriptional repressor MeCP1 shares a motif with DNA methyltransferase and HRX proteins.

Methylation of cytosines within the sequence CpG is essential for mouse development and has been linked to transcriptional suppression in vertebrate systems. Methyl-CpG binding proteins (MeCPs) 1 and 2 bind preferentially to methylated DNA and can inhibit transcription. The gene for MeCP2 has been cloned and a methyl-CpG binding domain (MBD) within it has been defined. A search of DNA sequence databases with the MBD sequence identified a human cDNA with potential to encode an MBD-like region. Sequencing of the complete cDNA revealed that the open reading frame also encodes two cysteine-rich domains that are found in animal DNA methyltransferases (DNMTs) and in the mammalian HRX protein (also known as MLL and All-1). HRX is related to Drosophila trithorax. The protein, known as Protein Containing MBD (PCM1), was expressed in bacteria and shown to bind specifically to methylated DNA. PCM1 also repressed transcription in vitro in a methylation-dependent manner. A polyclonal antibody raised against the protein was able to 'supershift' the native MeCP11 complex from HeLa cells, indicating that PCM1 is a component of mammalian MeCP1.

CpG methylation and the binding of YY1 and ETS proteins to the Surf-1/Surf-2 bidirectional promoter.

The divergently transcribed Surf-1 and Surf-2 genes are separated by a bi-directional, TATA-less promoter which contains three important factor-binding sites, Su1, Su2 and Su3. The transcription initiation factor YY1 binds to the Su1 site and stimulates transcription in the direction of Surf-1 and, to a lesser extent, Surf-2. Members of the ETS family of transcription factors bind to the Su2 and Su3 sites. Here we show that in transient transfection assays, transcription in both the Surf-1 and the Surf-2 direction is severely reduced by CpG methylation. Although the Su1 site contains three CpG dinucleotides, the binding of YY1 is not affected by CpG methylation. In contrast, the binding of two ETS factors (ETS-2 and PEA-3) to the Su2 site (which also contains three CpG dinucleotides) is totally abolished by CpG methylation. Finally, we show that methylation of a single C within the Su2 site is sufficient to prevent ETS factor binding.

CpG methylation has differential effects on the binding of YY1 and ETS proteins to the bi-directional promoter of the Surf-1 and Surf-2 genes.

The divergently transcribed Surf-1 and Surf-2 housekeeping genes are separated by a bi-directional, TATA-less promoter which lies within a CpG-rich island. Here we show that CpG methylation severely reduces transcription in the direction of both Surf-1 and Surf-2. Previous work has identified three promoter elements (Su1, Su2 and Su3) which are conserved between the human and mouse Surf-1/Surf-2 promoters. These elements bind transcription factors present in human and mouse cell nuclear extracts in vitro and mutations which prevent factor binding also reduce promoter activity in vivo. Transcription initiation factor YY1 binds to the Su1 site and stimulates transcription in the direction of Surf-1 and, to a lesser extent, Surf-2. Here we show that members of the ETS family of transcription factors bind to the Su2 site. Although the Su1 factor binding site contains three CpG dinucleotides, the binding of YY1 is not affected by CpG methylation. In contrast, CpG methylation abolishes the binding of ETS proteins to the Su2 site; methylation of a single cytosine, at position 3 of the consensus ETS site, is sufficient to prevent factor binding. This direct effect on the binding of ETS proteins is, however, not in itself sufficient to explain the repression of this promoter by CpG methylation. A mutation of the Su2 site which removes the sequence CpG, but which does not prevent ETS factor binding, fails to relieve this promoter from repression by CpG methylation.

Conformation of an enzyme-bound substrate of staphylococcal nuclease as determined by NMR.

The dinucleoside phosphodiester dTdA is a slow substrate of staphylococcal nuclease (kcat = 3.8 X 10(-3) s-1) that forms binary E-S and ternary E-M-S complexes with Ca2+, Mn2+, Co2+, and La3+. The enzyme enhances the paramagnetic effects of Co2+ on 1/T1 and 1/T2 of the phosphorus and on 1/T1 of six proton resonances of dTdA, and these effects are abolished by binding of the competitive inhibitor 3',5'-pdTp. From paramagnetic effects of Co2+ on 1/T2 of phosphorus, koff of dTdA from the ternary E-Co(2+)-dTdA complex is greater than or equal to 4.8 X 10(4) s-1 and kon greater than or equal to 1.4 X 10(6) M-1 s-1, indicating the 1/T1 values to be in fast exchange. From paramagnetic effects of enzyme-bound Co2+ on 1/T1 of phosphorus and protons, with use of a correlation time of 1.6 ps on the basis of 1/T1 values at 250 and 600 MHz, 7 metal-nucleus distances and 9 lower-limit metal-nucleus distances are calculated. The long Co2+ to 31P distance of 4.1 +/- 0.9 A, which is intermediate between that expected for direct phosphoryl coordination (3.31 +/- 0.02 A) and a second sphere complex with an intervening water ligand (4.75 +/- 0.02 A), suggests either a distorted inner sphere complex or the rapid averaging of 18% inner sphere and 82% second sphere complexes and may explain the reduced catalytic activity with small dinucleotide substrates. Seventeen interproton distances and 108 lower limit interproton distances in dTdA in the ternary E-La(3+)-dTdA complex were determined by NOESY spectra at 50-, 100-, and 200-ms mixing times. While metal-substrate and interproton distances alone did not yield a unique structure, the combination of both sets of distances yielded a very narrow range of conformations for enzyme-bound dTdA, which was highly extended, with no base stacking, with high-anti glycosidic torsional angles for dT (64 degrees less than or equal to chi less than or equal to 73 degrees) and dA (66 degrees less than or equal to chi less than or equal to 68 degrees) and predominantly C-2'-endo sugar puckers for both nucleosides. Although the individual nucleosides are like those of B-DNA, their unstacked conformation, which is inappropriate for base pairing, as well as the conformational angles alpha and gamma of dA and zeta of dT, rule out B-DNA.(ABSTRACT TRUNCATED AT 400 WORDS)

CpG methylation inhibits binding of several sequence-specific DNA-binding proteins from pea, wheat, soybean and cauliflower.

To elucidate how methylation of specific sites in plant DNA might control transcription, we examined the effect of DNA methylation at CpG sequences on the binding of plant nuclear factors to an oligonucleotide duplex containing the consensus sequence for mammalian CREB (cAMP response element binding protein). CREB is part of the ATF (activating transcription factor) family of mammalian proteins specifically binding to 5'-TGACGTCA-3' and related sequences. Proteins recognizing the CREB-specific ligand were identified in nuclear extracts of pea seeds, wheat germ, cauliflower, and soybean leaves using electrophoretic mobility shift assays. Cytosine methylation inhibited binding of this protein in all these extracts, and so this sequence-specific DNA-binding activity is referred to as methylation-inhibited binding protein 1 (MIB-1). Sites somewhat similar to that of the CREB ligand are found in the upstream regions of a wheat histone H3 gene and tomato and pea ribulose 1,5-bisphosphate carboxylase genes. These sites were bound preferentially by distinct proteins that may be related to the previously described plant proteins HBP-1, HSBF, ASF-1, or GBF. Methylation of cytosine residues at these sites and at a site for MIB-1 located upstream of a soybean proline-rich protein gene also reduced specific binding with all the nuclear extracts tested. Similarly, substitution of the central CpG dinucleotide with TpG decreased binding.

Synthesis of (Rp,Rp)-P1,P4-Bis(5'-adenosyl)-1[17O,18O2],4[17O,18O2] tetraphosphate from (Sp,Sp)-P1,P4-Bis(5'-adenosyl)-1[thio-18O2], 4[thio-18O2]tetraphosphate with retention at phosphorus and the stereochemical course of hydrolysis by the unsymmetrical Ap4A phosphodiesterase from lupin seeds.

The three stereoisomers of P1,P4-bis(5'-adenosyl)-1,4-dithiotetraphosphate have been synthesized and their 31P NMR spectra investigated. The effect of temperature on the circular dichroic spectrum of the (Sp,Sp)-stereoisomer shows that unstacking of the molecule occurs as the temperature is raised. Treatment of the (Sp,Sp)-stereoisomer with cyanogen bromide in [18O]water leads to substitution of sulfur by 18O with predominant retention of configuration at P1 and P4. (Sp,Sp)-P1,P4-Bis(5'-adenosyl)-1[thio-18O2],4[thio-18O2]tetraphosphate was synthesized and on treatment with cyanogen bromide in [17O]water gave (Rp,Rp)-P1,P4-bis(5'-adenosyl)-1[17O,18O2],4[17O,18O2]tetraphosphate. Hydrolysis by unsymmetrical Ap4A phosphodiesterase from lupin seeds gave (Rp)-5'-[16O,17O,18O]AMP. The reaction therefore proceeds with inversion of configuration at phosphorus, indicating that the enzyme-catalyzed displacement by water occurs by a direct "in-line" mechanism.