Parallel-stranded hairpins containing 8-aminopurines. Novel efficient probes for triple-helix formation.

We describe novel oligomers with a greater propensity to form triplexes than oligomers containing only natural bases. They consist of a polypyrimidine sequence linked head-to-head with a polypurine sequence carrying one or several 8-aminoadenine or 8-aminoguanines. The presence of 8-aminopurines also stabilised the parallel-stranded duplex structure.     

Preparation of trimers and tetramers of mixed sequence oligodeoxynucleoside methylphosphonates and assignment of configurations at the chiral phosphorus.

Synthesis of stereoregular DNA methylphosphonates has been accomplished for homo-oligomers, but remains a formidable problem for oligomers of a defined antisense target sequence. In this work, four trimer and tetramer deoxynucleoside methylphosphonates of mixed sequence (dACA, dCCAA, dAGGG, and dGCAT) were prepared by block coupling of diastereomerically pure dimers with either monomers or other diastereomerically pure dimers. These oligomers were separated chromatographically into individual diastereomers, and the configurations of the chiral methylphosphonate linkages were assigned. Three types of methods were used to assign configuration of a new methylphosphonate linkage: preparation of the same diastereomer through multiple synthetic pathways, base hydrolysis, and acid hydrolysis. Hydrolysis of the diastereomerically pure oligomers into component dimers and monomers was followed by chromatographic comparison with control dimers of known configuration. In all cases studied, oligomers with R configurations displayed faster elution from silica gel than did oligomers with the respective S configuration. NMR spectra of individual diastereomers of dACA were studied, revealing characteristic differences in chemical shifts which may prove useful in configurational assignments of longer oligomers. Thus, these data provide a methodological basis for synthesis and configurational assignment of longer methylphosphonate oligomers to use as antisense probes.     

Vaccination with a non-human random sequence amyloid oligomer mimic results in improved cognitive function and reduced plaque deposition and micro hemorrhage in Tg2576 mice

ABSTRACT: BACKGROUND: It is well established that vaccination of humans and transgenic animals against fibrillar amyloid beta (Abeta) prevents amyloid accumulation in plaques and preserves cognitive function in transgenic mouse models. However, autoimmune side effects have halted the development of vaccines based on full length human Abeta. Further development of an effective vaccine depends on overcoming these side effects while maintaining an effective immune response. RESULTS: We have previously reported that the immune response to amyloid oligomers is largely directed against generic epitopes that are common to amyloid oligomers of many different proteins and independent of a specific amino acid sequence. Here we have examined whether we can exploit this generic immune response to develop a vaccine that targets amyloid oligomers using a non-human random sequence amyloid oligomer. In order to study the effect of vaccination against generic oligomer epitopes, a random sequence oligomer (3A) was selected as it forms oligomers that react with the oligomer specific A11 antibody. Oligomer mimics from 3A peptide, Abeta, islet amyloid polypeptide (IAPP), and Abeta fibrils were used to vaccinate Tg2576 mice, which develop a progressive accumulation of plaques and cognitive impairment. Vaccination with the 3A random sequence antigen was just as effective as vaccination with the other antigens in improving cognitive function and reducing total plaque load (Abeta burden) in the Tg2576 mouse brains. CONCLUSION: These results show that the amyloid Abeta sequence is not necessary to produce a protective immune response that specifically targets generic amyloid oligomers. Using a non-human, random sequence antigen may facilitate the development of a vaccine that avoids autoimmune side effects.     

Sequence dependent electrophoretic mobilities and melting temperatures for A-T containing oligodeoxyribonucleotides.

The electrophoretic mobilities and thermal melting properties of self complementary A-T containing dodecamer oligodeoxyribonucleotides have been investigated as a function of solution conditions. The oligomers contained tracts of nonalternating A-T base pairs of 2 (d(A2T2)3), 3 (d(A3T3)2), and 6 (d(A6T6] as well as the fully alternating (d(A-T)6) sequence. The melting temperature increased with the length of the nonalternating sequence and was approximately 12 degrees C higher in the d(A6T6) sequence than in the alternating oligomer. Under denaturing conditions all oligomers had the same electrophoretic mobility on acrylamide gels. Under conditions which favor duplex formation, the oligomers exhibited significant sequence dependent mobility differences. The mobilities of two oligomers, d(A-T)6 and d(A6-T6), were approximately equal and were less than those of the other oligonucleotides. The greatest mobility was observed for d(A2T2)3. These results are best explained by a model which requires bending at a junction of two or more continuous A or T bases with another sequence.     

Probability of occurrence of specific oligomers.

We improved an already existing formula for calculating the probability of occurrence of specific oligomers (Grob & Stüber, 1987) by taking into account unequal base distribution. This method identifies specific oligomers in a given sequence as candidates for biological signals.     

Assessing the sequence specificity in the binding of Co(III) to DNA via a thermodynamic approach

The interaction specificities of Co(III) with DNA were investigated via consideration of thermodynamic characteristics of the duplex to single strand transition for DNA oligomers incubated in the presence of [Co(NH₃)₅(OH₂)] (ClO₄)₃. It has previously been demonstrated that incubation of the DNA oligomer [(5medC-dG)₄]₂ with this cobalt complex leads to coordination of the cobalt center to the DNA, presumably at N7 of guanine bases [D. C. Calderone, E. J. Mantilla, M. Hicks, D. H. Huchital, W. R. Murphy, Jr. and R. D. Sheardy, (1995) Biochemistry 34, 13841]. In this report, DNA oligomers of different sequence were incubated with [Co(NH₃)₅(OH₂)] (ClO₄)₃ via protocols developed previously and the treated oligomers were subjected to thermal denaturation for comparison to the untreated oligomers. The DNA oligomers were designed in order to investigate the sequence specificity, if any, in the reaction of the cobalt complex with DNA. The values of T_m, ΔH_uH, and Δn (the differential ion binding term) obtained from the thermal denaturations were used to assess the sequence specificity of the interaction. For all oligomers, treated or untreated, T_m and Δ_uH vary linearly with log [Na⁺] and hence the value of Δn is a function of the Na⁺ concentration. The results indicate no significant reaction between the cobalt complex and oligomers possessing isolated -GA- or -CG- sites; however, the thermodynamic characteristics of DNA oligomers possessing either an isolated -GG- site or an isolated -GC- site were altered by the treatment. Atomic absorption studies of the treated oligomers demonstrate that only the DNA oligomers possessing isolated -GG- or -GC- sites bind cobalt. Hence, the changes in the thermodynamic properties of these oligomers are a result of cobalt binding with a remarkable sequence specificity. © 1997 John Wiley & Sons, Inc. Biopoly 42: 549–599, 1997     

Prediction of 1H NMR chemical shifts of DNA oligomers

A set of parameters, devised for the prediction of 1H NMR chemical shifts of heterobase and anomeric protons in the high temperature (greater than 70 degrees C) spectra of RNA oligomers has been found to be applicable to the corresponding DNA oligomers. Fifteen examples of DNA oligomers that have had high temperature spectra recorded and assigned show a mean absolute difference between predicted and assigned shifts of 0.045 ppm. The parameters for uridine H-5 are applied to the calculation of thymidine methyl group shifts and give excellent agreement with experimental assigned shifts. The RNA parameter set is a practical means of assigning heterobase and anomeric protons in DNA oligomers. A programme using the RNA parameter set has been written which enables the sequence of short DNA oligomers to be predicted from their 1H NMR spectra.     

Overlapping redundant septuplets identical with regulatory elements of HIV-1 and SV40.

Overlapping redundant short oligomers in DNA sequences of retroviruses and papovaviruses have been identified. For each sequence, a search procedure determines the 5% short oligomers of the same length with the highest ratios of observed to expected occurrences based on singlet composition of the sequence. These short oligomers are referred to as compositionally-assessed redundant sequence elements (COARSEs). A pair of COARSEs overlapping by at least one base is considered to be a COARSE overlap. Most COARSE overlaps of the 7th order (overlapping septuplets) are found in long terminal repeats of retroviruses and in the regulatory control regions of papovaviruses SV40, BK and JC. Many of the 7th order COARSE overlaps in HIV-1 and SV40 are identical with regulatory elements determined experimentally. On the contrary, very few of the most frequently occurring oligomer overlaps, which are defined differently from COARSE overlaps, are present in the regulatory regions of retroviruses and papovaviruses. Examining DNA sequences of other genomes by the COARSE overlap method may identify putative regulatory regions.     

BanI restriction endonuclease binds in the major groove of DNA: an inhibition kinetic study using substrates with mismatch basepairs

Structural information on BanI-DNA interaction was obtained from simple inhibition kinetic assays using altered substrates. Self-complementary 13-mer oligodeoxynucleotides with or without mismatch basepairs in the BanI recognition sequence (GGPyPuCC) were synthesized. UV melting curves and CD spectra indicated double-stranded B-DNA structure for all the oligomers. Among the seven oligomers with recognition sequences, GGTACC, GGTGCC, GGTATC, GGCACC, GGAGCC, GGTAAC, and GGATCC, only the first two were cleaved with BanI. Kinetics of BanI cleavage of the native substrate was inhibited competitively by all of the other oligomers except the one with sequence GGCACC. From inhibition kinetic analysis in presence of a fixed concentration of the inhibitor, apparent K(m) and K(I) were determined. The data were analyzed in the context of alterations made in the hydrogen bonding potential in the major and minor groove of DNA within the recognition sequence due to basepair mismatches. Such analyses led to the conclusion that BanI, like BamHI, binds in the major groove and the central thymines make important contact with the protein.     

Permeabilization of lipid bilayers is a common conformation-dependent activity of soluble amyloid oligomers in protein misfolding diseases

Amyloid fibrillization is multistep process involving soluble oligomeric intermediates, including spherical oligomers and protofibrils. Amyloid oligomers have a common, generic structure, and they are intrinsically toxic to cells, even when formed from non-disease related proteins, which implies they also share a common mechanism of pathogenesis and toxicity. Here we report that soluble oligomers from several types of amyloids specifically increase lipid bilayer conductance regardless of the sequence, while fibrils and soluble low molecular weight species have no effect. The increase in membrane conductance occurs without any evidence of discrete channel or pore formation or ion selectivity. The conductance is dependent on the concentration of oligomers and can be reversed by anti-oligomer antibody. These results indicate that soluble oligomers from many types of amyloidogenic proteins and peptides increase membrane conductance in a conformation-specific fashion and suggest that this may represent the common primary mechanism of pathogenesis in amyloid-related degenerative diseases.     

Synthesis of Protected 8-Substituted Deoxyribonucleosides and Its Helix Stability in Oligodeoxyribonucleotides Containing the Eco RI Recognition Site

Abstract

Octadeoxyribonucleotides with the sequences d(GGA?ATTCC), d(GGAA?TTCC), and d(GG?AATTCC) have been prepared by solid phase synthesis using the H-phosphonate units containing modified base moieties. These oligomers which have an isosterically altered recognition sequence of the restriction endodeoxyribonuclease Eco RI. The oligomers, with replacement to deoxy-7,8-dihyroadenosine-8-one (dA^OH), 8-methoxydeoxyadenosine (dA_OMe) and 8-methoxydeoxyguanosine (dG^OMe) from deoxyadenosine or deoxyguanosine were used for studying recognition phenomena at the functional group level. From thermodyamic data of these alternating octamers it was shown that the oligomer containing 8-methoxydeoxyadenosine in the center of the recognition sequence destabilizes such duplexes less strongly than the oligomers containing other 8-substituted nucleosides in the 5′-side of the recognition sequences. Further, the hydrolysis by Eco RI of the modified oligomers perfectly resisted compared to d(GGAATTCC).     

Sequential oligopeptides. Synthesis and characterization of the oligopeptides and a polypeptide with the repeating sequence L-norvalyl-glycyl-L-proline

The synthesis and characterization of a series of oligopeptides (from the tripeptide to the octadecapeptide) with the repeating sequence L -norvalyl-glycyl-L -proline and a polytripeptide with this sequence are reported. The oligomers were synthesized step by step using the mixed anhydride method. All the products were chemically and optically pure. The polymer was prepared by the active ester method, using the p-nitrophenyl ester as the polymerizable tripeptide derivative. Good yield of relatively high average molecular-weight polymer was obtained. In the accompanying paper conformational investigations, both in solution and in the solid state, on the oligomers and the polymer are described.     

Computing highly specific and noise-tolerant oligomers efficiently

The sequencing of the genomes of a variety of species and the growing databases containing expressed sequence tags (ESTs) and complementary DNAs (cDNAs) facilitate the design of highly specific oligomers for use as genomic markers, PCR primers, or DNA oligo microarrays. The first step in evaluating the specificity of short oligomers of about 20 units in length is to determine the frequencies at which the oligomers occur. However, for oligomers longer than about fifty units this is not efficient, as they usually have a frequency of only 1. A more suitable procedure is to consider the mismatch tolerance of an oligomer, that is, the minimum number of mismatches that allows a given oligomer to match a substring other than the target sequence anywhere in the genome or the EST database. However, calculating the exact value of mismatch tolerance is computationally costly and impractical. Therefore, we studied the problem of checking whether an oligomer meets the constraint that its mismatch tolerance is no less than a given threshold. Here, we present an efficient dynamic programming algorithm solution that utilizes suffix and height arrays. We demonstrated the effectiveness of this algorithm by efficiently computing a dense list of numerous oligo-markers applicable to the human genome. Experimental results show that the algorithm runs faster than well-known Abrahamson's algorithm by orders of magnitude and is able to enumerate 65% approximately 76% of qualified oligomers.     

Aromatic small molecules remodel toxic soluble oligomers of amyloid beta through three independent pathways

In protein conformational disorders ranging from Alzheimer to Parkinson disease, proteins of unrelated sequence misfold into a similar array of aggregated conformers ranging from small oligomers to large amyloid fibrils. Substantial evidence suggests that small, prefibrillar oligomers are the most toxic species, yet to what extent they can be selectively targeted and remodeled into non-toxic conformers using small molecules is poorly understood. We have evaluated the conformational specificity and remodeling pathways of a diverse panel of aromatic small molecules against mature soluble oligomers of the Aβ42 peptide associated with Alzheimer disease. We find that small molecule antagonists can be grouped into three classes, which we herein define as Class I, II, and III molecules, based on the distinct pathways they utilize to remodel soluble oligomers into multiple conformers with reduced toxicity. Class I molecules remodel soluble oligomers into large, off-pathway aggregates that are non-toxic. Moreover, Class IA molecules also remodel amyloid fibrils into the same off-pathway structures, whereas Class IB molecules fail to remodel fibrils but accelerate aggregation of freshly disaggregated Aβ. In contrast, a Class II molecule converts soluble Aβ oligomers into fibrils, but is inactive against disaggregated and fibrillar Aβ. Class III molecules disassemble soluble oligomers (as well as fibrils) into low molecular weight species that are non-toxic. Strikingly, Aβ non-toxic oligomers (which are morphologically indistinguishable from toxic soluble oligomers) are significantly more resistant to being remodeled than Aβ soluble oligomers or amyloid fibrils. Our findings reveal that relatively subtle differences in small molecule structure encipher surprisingly large differences in the pathways they employ to remodel Aβ soluble oligomers and related aggregated conformers.     

Distance analysis and sequence properties of functional domains in nucleic acids and proteins

We present a unified algorithm to analyze distances between short oligomers in large collections of nucleic acids and protein sequences (DISTANP). This extended version of DISTAN methodology not only permits analysis of distances between selected pairs of oligomers, but also allows a user to analyze distances between groups of residues (such as acidic and hydrophobic amino acids). This capacity allows differentiation of sequence properties of known functional domains in nucleic acids and proteins.     

Concentration and Extinction Coefficient Determination for Oligonucleotides and Analogs Using a General Phosphate Analysis

A general phosphate analysis (GPA) is developed which assays the concentration of nucleic acid oligomers and their analogs based on stoichiometric phosphorus in the sequence. The method involves complete digestion of the oligomer sample to orthophosphate using acid at high temperature and subsequent colorimetric analysis by phosphomolybdate complex formation. GPA is applied to oligomers having phosphodiester, methylphosphonate, and phosphorothioate backbone linkages. Given the absorption spectra of oligomers having these backbones, extinction coefficients are obtained and compared to other quantitative and predictive methods. In addition to sequences having the usual nucleoside residues found in naturally occurring nucleic acids, oligomers having base analog residues can be readily quantified by GPA.     

Static and dynamic conformational properties of AT sequences in B-DNA.

A theoretical study of the optimal conformations of nucleic acid oligomers containing tracts of AT base pairs is presented. The oligomers are studied in isolation and complexed with netropsin, a minor groove binding ligand. The flexibility of the oligomers and of their complexes is calculated by adiabatic mapping with respect to the total winding angle. The results of this study show that in uncomplexed oligomers the dinucleotide junctions AA, AT and TA have very different structural parameters and different responses to winding stress. The TA junction is clearly the most flexible and is the principal site for accommodating the imposed overwinding. Complexation by netropsin leads to two important effects: firstly, the three junctions adopt more uniform structures, the largest changes again being observed for TA, secondly, the differences in flexibility as a function of sequence are strongly attenuated.