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  4. ... em Descoberta de Medicamentos
  5. SELEX/Modificação de Aptâmeros

Nucleotídeos para SELEX/Modificação de Aptâmeros


Produtos

2'-Fluoro-dUTP NU-1215

(2'F-dUTP)  

2'-Fluoro-dCTP NU-1214

(2'F-dCTP)  

2'-Fluoro-dATP NU-151

(2'F-dATP)  

2'-Fluoro-dGTP NU-1216

(2'F-dGTP)  

2'-Fluoro-dNTP Bundle NU-10405

(2'F-dNTP Bundle)  

2'OMe-UTP NU-1212

 

2'OMe-CTP NU-1211

 

2'OMe-ATP NU-1184

 

2'OMe-GTP NU-1127

 

2'NH2-dUTP NU-242

 

2'NH2-dCTP NU-243

 

2'NH2-dATP NU-244

 

2'NH2-dGTP NU-245

 

LNA-ATP NU-982

 

LNA-GTP NU-983

 

LNA-CTP NU-984

 

LNA-UTP NU-985

 

5-Bromo-dUTP NU-122

(5Br-dUTP)  

5-Iodo-UTP NU-119

(5I-UTP)  

4-Thio-UTP NU-1156

s4UTP, 4sUTP  

Selected References

[1] Hermann et al. (2000) Adaptive recognition by nucleic acid aptamers. Science 287:820.
[2] Stoltenburg et al. (2007) SELEX-A (r)evolutionary method to generate high-affinity nucleic acids ligands. Biomolecular Engineering 24:381.
[3] Lauridsen et al. (2012) Enzymatic Recognition of 2'-Modified Ribonucleoside 5'-Triphosphates: Towards the Evolution of Versatile Aptamers. Chem. Bio. Chem. 13:19.
[4] Keefe et al. (2008) SELEX with modified nucleotides. Current Opinion in Chemical Biology 12:448.
[5] Ono et al. (1997) 24-Fluoro modified nucleic acids: polymerase-directed synthesis, properties and stability to analysis by matrix-assisted laser desorption/ionization mass spectrometry. Nucleic Acids Research 25 (22):4581.
[6] Aurup et al. (1992) 2'-Fluoro and 2-amino-2'-deoxynucleoside 5'-triphosphates as substrates for T7 RNA polymerase. Biochemistry 31 (40):9626.
[7] Adler et al. (1998) POST-SELEX Chemical Optimization of a trypanosome-specific RNA aptamer. Comb. Chem. High Throughput Screen. 11 (1):16.
[8] Burmeister et al. (2005) Direct In Vitro Selection of a 2'-O-Methyl Aptamer to VEGF. Chemistry & Biology 12:25.
[9] Burmeister et al. (2006) 2'-Deoxy Purine, 2'-O-Methyl Pyrimidine (dRmY) Aptamers as Candidate Therapeutics. OLIGONUCLEOTIDES 16:337.
[10] Padilla et al. (1999) Efficient synthesis of nucleic acids heavily modified with non-canonical ribose 2'-groups using a mutant T7 RNA Polymerase (RNAP). Nucleic Acids Res. 27 (6):156.
[11] Padilla et al. (2002) A Y639F/H784A T7 RNA polymerase double mutant displays superior properties for synthesizing RNAs with non-canonical NTPs. Nucleic Acids Res. 30 (24):e138.
[12] Lin et al. (1994) Modified RNA sequence pools for in vitro selection. Nucleic Acids Res. 22 (24):5229.
[13] Golden et al. (2000) Diagnostic potential of PhotoSELEX-evolved ssDNA aptamers. Journal of Biotechnology 81:167.
[14] Jensen et al. (1995) Using in vitro selection to direct the covalent attachment of human immunodeficiency virus type 1 Rev protein to high-affinity RNA ligands. Proc. Natl. Acad. Sci. USA 92:12220.
[15] Park et al. (2008) Higher-Order Association States of Cellular ERBB3 Probed with Photo-Cross-Linkable Aptamers. Biochemistry 47 (46):11992.
[16] Crouzier et al. (2012) Efficient reverse transcription using locked nucleic acid nucleotides towards the evolution of nuclease resistant RNA aptamers. PLoS One. 7 (4):e35990.