4‐Thio‐deoxyuridylate‐modified thrombin aptamer and its inhibitory effect on fibrin clot formation, platelet aggregation and thrombus growth on subendothelial matrix

Raviv, Shlomit Mendelboum; Horváth, András; Aradi, J.; Bagoly, Zsuzsa; Fazakas, Ferenc; Batta, Z.; Muszbek, László; Hársfalvi, Jolán

doi:10.1111/j.1538-7836.2008.03106.x

Cited by 42 publications

(35 citation statements)

References 36 publications

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“…An RNA aptamer targeting the Most of these are aided by the medicinal chemistry approach, with the fast development of organic synthesis serving as a toolbox [10]. As a result of chemical modifications, many exceptional characteristics besides stability such as improved specificity [11], increased affinity [12][13][14][15], enhanced delivery and prolonged plasma residence [7,[16][17][18][19][20][21][22][23] have been reported and summarized [1,[3][4][5]10,24,25], among which aptamers conjugated by polyethylene glycol significantly promote aptamer's bio-distribution to varied tissues and organs in vivo and increase their plasma retention time, with prolonged half-lives for blood clearance [16,22]. Aptamers can be also encapsulated in or attached to biodegradable polymers/proteins for sustained drug delivery and prolonged release in vivo [18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Improving the Stability of Aptamers by Chemical Modification

Wang

Wu²,

Niu³

et al. 2011

CMC

145

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Ever since the invention of SELEX (systematic evolution of ligands by exponential enrichment), there has been rapid development for aptamers over the last two decades, making them a promising approach in therapeutic applications as either drug candidates or diagnostic tools. For therapeutic purposes, a durable performance of aptamers in biofluids is required, which is, however, hampered by the lack of stability of most aptamers. Not only are the nucleic acid aptamers susceptible to nucleases, the peptide aptamers are also subjective to degradation by proteases. With the advancement of chemical biology, numerous attempts have been made to overcome this obstacle, many resulting in significant improvements in stability. In this review, chemical modifications to increase the stability of three main types of aptamers, DNA, RNA and peptide are comprehensively summarized. For nucleic acid aptamers, development of modified SELEX coupled with mutated polymerase is discussed, which is adaptive to a number of modifications in aptamers and in a large extent facilitates the research of aptamer-modifications. For peptide aptamers, approaches in molecular biology with introduction of stabilizing protein as well as the switch of scaffold protein are included, which may represent a future direction of chemical conjugations to aptamers.

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Section: Introductionmentioning

confidence: 99%

Improving the Stability of Aptamers by Chemical Modification

Wang

Wu²,

Niu³

et al. 2011

CMC

145

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“…In various strategies TBA 15 maintained its natural backbone and was only modified in the sequence: 1) by substituting several bases in the loops and/or in the G-quartets (Smirnov & Shafer, 2000; Saccà et (Uehara et al, 2008;Buff et al, 2010). Some researchers have exploited non-natural modifications of the nucleobases (Krawczyk et al, 1995;He et al, 1998a;Marathias et al, 1999;López de la Osa et al, 2006;Mendelboum Raviv et al, 2008;Nallagatla et al, 2009;Goji & Matsui, 2011), which included: 1) guanines modified with hydrophobic substituents in the N 2 and C 8 positions; 2) 6-thio-, 3) 8-amino-, 4) iso-, and 5) 8-bromo-guanine modifications; and 6) thymine with 4-thio-uracil substitutions. Other research groups modified the nucleotide backbone of TBA 15 by introducing valuable surrogates replacing the natural phosphodiester linkages, such as: 1) neutral formacetal groups (He et al, 1998b), 2) phosphorothioate linkages (Saccà et al, 2005;Pozmogova et al, 2010;Zaitseva et al, 2010), 3) 3′-3′ or 5′-5′ phosphodiester bonds (Martino et al, 2006;Esposito et al, 2007;Pagano et al, 2008;Russo Krauss et al, 2011), and 4) methylphosphonate bonds (Saccà et al, 2005), or the nucleoside moieties, with insertion within the backbone of: 5) 2′-deoxy-2′-fluoro-D-arabinonucleotides (2′F-araN) (Peng & Damha, 2007), 6) locked-nucleic acids Bonifacio et al, 2008), 7) unlocked nucleic acids (UNA) (Agarwal et al, 2011;Jensen et al, 2011;Pasternak et al, 2011), and 8) acyclic thymine nucleoside (Coppola et al, 2008) residues.…”

Section: The Thrombin Binding Aptamers (Tbas)mentioning

confidence: 99%

Polyvalent nucleic acid aptamers and modulation of their activity: a focus on the thrombin binding aptamer

Musumeci¹,

Montesarchio²

2012

Pharmacology & Therapeutics

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“…Typically, the modifications affected either central loop only or in combination with selected thymines in TT loops as described for isodeoxyguanosine, 2′-fluoroarabinose, 4-thio, and unlocked TBA analogs. 13,14,17,36 Because the central loop is the most exposed region in the TBA structure 8,35 its modification may considerably improve nuclease resistance of chimeric aptamers. Anomeric modification in the TGT loop was shown to dramatically increase nuclease resistance.…”

Section: Discussionmentioning

confidence: 99%

“…studies on TBA analogs containing 3′-3′ and 5′-5′ junctions, LNA residues, internucleotide phosphorothioates, 2′-fluoroarabinose, isodeoxyguanosine and several other modified nucleotides have been reported. [11][12][13][14][15][16][17][18] Enhanced binding affinity to thrombin and improved anticoagulant and antithrombotic properties have been observed for certain TBA modifications. [11][12][13] In this study, we report the modification of TBA with anomeric α-nucleotides (Fig.…”

Section: Introductionmentioning

confidence: 99%