A 5′‐Cap for DNA Probes Binding RNA Target Strands

Egetenmeyer, Simone; Richert, Clemens

doi:10.1002/chem.201101828

Cited by 20 publications

(24 citation statements)

References 94 publications

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“…For cleavage and deprotection of the DNA, the CPG was treated with aqueous ammonia (27%, 1 ml) and heated to 60EC for 2 h. The oligonucleotides were purified using C18 cartridges (Sep-Pak Vac 3cc) from Waters (Milford, MA, USA) with triethylammonium acetate buffer (0.1 M, pH 7) and a step gradient of CH 3 CN. Molecular caps U AQ and ogOA, shown in Figures 4 and 5, were introduced following the methods described earlier Egetenmeyer, 2011). The analytical data and MALDI-TOF mass spectra of modified oligonucleotides are provided in the supporting information.…”

Section: Methodsmentioning

confidence: 99%

“…This length range also encompasses the number of nucleotides found in microRNAs, whose selective detection in clinical samples is a diagnostic challenge (Wark, 2008). It has been previously reported that full length probes perform poorly in detecting microRNAs differing by just one nucleotide (Egetenmeyer, 2011), prompting the question whether segmenting longer hybridization probes into a series of shorter hybridization probes would lead to a better compromise between affinity and selectivity. Here we report the results from an experimental study into this issue.…”

Section: Introductionmentioning

confidence: 99%

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RESEARCH PAPER Segmented hybridization probes: modulating target affinity and base pairing selectivity

Egetenmeyer¹,

Geiger²,

Richert³

2012

bta

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Short hybridization probes bind their targets with greater base pairing fidelity, but with lower affinity than longer probes. Furthermore, their target sequence is shorter, and thus more likely not to be unique in a given genome. Long hybridization probes provide increased affinity, and their sequences are more unique, but their duplexes tolerate mismatches more readily, without a significant depression in melting point. It was reasoned that segmenting longer hybridization probes by introducing flexible, abasic linkers might lead to oligonucleotides that retain some of the sequence selectivity of short probes without losing too much of the target affinity of their unsegmented counterparts. A model study led to 1,3-propandiol-phosphates as linker residues. These spacer residues were introduced at different positions of hybridization probes 8-20 residues in length and their hybridization properties were studied in UV-melting curves with RNA or DNA target strands. Increases in base pairing selectivity (ΔΔTm of up to !7.4EC for a single mismatch) and decreased target affinities (ΔTm between !15 and !25EC) were found for the segmented probes when compared to their unsegmented counterparts, and so was a decreased selectivity for insertions at the site of the linker. Also, the increases in selectivity are not uniform in their magnitude and depend on sequence context and position. A favorable case appears to be a hybridization probe that contains two spacers, with one octamer as core segment, flanked by a heptamer and a pentamer as terminal segments.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

RESEARCH PAPER Segmented hybridization probes: modulating target affinity and base pairing selectivity

Egetenmeyer¹,

Geiger²,

Richert³

2012

bta

Self Cite

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“…We will point out the difficulties and limitations of the different strategies and – if available – will show ways to circumvent them. This review focuses strictly on mRNA cap analogues (and some non-natural modifications); for preparation of other capped biomolecules such as capped siRNAs [ 21 ], peptidyl capped oligonucleotides [ 22 ], NAD-capped RNAs [ 23 – 24 ], 3'-dephospho-CoA linked RNA [ 25 ] or methylphosphate capping [ 26 – 27 ] we refer to the indicated articles.…”

Section: Introductionmentioning

confidence: 99%

Synthetic mRNA capping

Muttach¹,

Muthmann²,

Rentmeister³

2017

Beilstein J. Org. Chem.

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Eukaryotic mRNA with its 5′-cap is of central importance for the cell. Many studies involving mRNA require reliable preparation and modification of 5′-capped RNAs. Depending on the length of the desired capped RNA, chemical or enzymatic preparation – or a combination of both – can be advantageous. We review state-of-the art methods and give directions for choosing the appropriate approach. We also discuss the preparation and properties of mRNAs with non-natural caps providing novel features such as improved stability or enhanced translational efficiency.

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“…High levelso f adaptation and refinement have been achieved in studies on the in vitro evolution of polymerizing enzymes, [1][2][3] and it has been shown that genetici nformation can be stored in and recovered from alternative genetic polymers based on nucleic acid architectures not found in nature. [4] High-yieldinga nalytically powerful nonenzymatic polymerization methodologies have also been developed, [5][6][7][8][9][10][11][12][13] enabling in vitro studies on molecular evolution and supporting the Darwinian logics pioneered by Spiegelman. [14] Complex chemistries involved in the nonenzymatic polymerization of highenergy monomers to nucleic acids are well described in the literature.…”

Section: Introductionmentioning

confidence: 99%

“…The efficiencyo ft he polymerization reactioni sd etermined by the extento fp hosphate activation and the properties of the leaving group. High-yieldingt emplate-directed RNA syntheses are commonly performed with 5'-phosphorimidazoliden ucleosides [9][10][11][12][13][14][15][16] or one of the numerous variants thereof, [17,18] because imidazole and its derivatives are good leaving groups. These are all high-energyc ompounds that polymerizee fficiently,b ut the likelihood of their prebiotic availability and accumulationi s inverselyp roportionalt ot heir intrinsic stability and the elaborate nature of the chemistry necessary fort heir synthesis.…”

Section: Introductionmentioning

confidence: 99%

Nonenzymatic Oligomerization of 3′,5′‐Cyclic CMP Induced by Proton and UV Irradiation Hints at a Nonfastidious Origin of RNA

et al. 2017

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We report that 3',5'-cyclic CMP undergoes nonenzymatic di- and trimerization at 20 °C under dry conditions upon proton or UV irradiation. The reaction involves stacking of the cyclic monomers and subsequent polymerization through serial transphosphorylations between the stacked monomers. Proton- and UV-induced oligomerization of 3',5'-cyclic CMP demonstrates that pyrimidines-similar to purines-might also have taken part in the spontaneous generation of RNA under plausible prebiotic conditions as well as in an extraterrestrial context. The observed polymerization of naturally occurring 3',5'-cyclic nucleotides supports the possibility that the extant genetic nucleic acids might have originated by way of a straight Occamian path, starting from simple reactions between plausibly preactivated monomers.

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A 5′‐Cap for DNA Probes Binding RNA Target Strands

Cited by 20 publications

References 94 publications

RESEARCH PAPER Segmented hybridization probes: modulating target affinity and base pairing selectivity

RESEARCH PAPER Segmented hybridization probes: modulating target affinity and base pairing selectivity

Synthetic mRNA capping

Nonenzymatic Oligomerization of 3′,5′‐Cyclic CMP Induced by Proton and UV Irradiation Hints at a Nonfastidious Origin of RNA

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