TY - JOUR
T1 - Design, synthesis and evaluation of light-activatable organic molecules that target-selectively degrade dna, proteins and carbohydrates; An interdisciplinary challenge for a synthetic organic chemist
AU - Toshima, Kazunobu
N1 - Copyright:
Copyright 2012 Elsevier B.V., All rights reserved.
PY - 2012
Y1 - 2012
N2 - We developed chemical methods for target-selective photodegradation of various biomacromolecules, including DNA, proteins, and carbohydrates. The DNA intercalator-carbohydrate moiety, without the enediyne structure found in the enediyne antibiotic neocarzinostatin chromophore, selectively degrades duplex DNA at guanine (G) nucleotides upon photoirradiation. Based on this finding, we designed and synthesized several artificial DNA intercalator-carbohydrate hybrids that can be photoactivated. Among them, several quinoxaline-carbohydrate hybrids were found to photodegrade duplex DNA at the G on the 5 side of 5-GG-3 sites. For protein degradation, we designed and synthesized several 2-phenylquinoline-steroid hormone hybrids and a porphyrin derivative, both of which selectively photodegrade the transcription factor estrogen receptor-α. In addition, we designed and synthesized fullerene-sugar and fullerene-sulfonic acid hybrids that selectively photodegrade HIV-1 protease and amyloid β, respectively. For carbohydrate degradation, we designed and synthesized anthraquinone-lectin hybrids and anthraquinone- and fullerene-boronic acid hybrids for selective photodegradation of target oligosaccharides having affinity for the lectin or boronic acid moiety of the hybrids. Furthermore, we successfully demonstrated practical uses for these light-activatable and molecular-targeted (LAMTA) molecules for controlling the function of DNA, proteins, and carbohydrates both in glass vessels and in cells. 1 Introduction 2 DNA Photodegrading Organic Molecules 2.1 DNA Intercalator-Carbohydrate Hybrids 2.2 Neocarzinostatin DNA Intercalator- Carbohydrate Hybrids for DNA Photodegradation 2.3 Quinoxaline-Carbohydrate Hybrids for DNA Photodegradation 3 Protein Photodegrading Organic Molecules 3.1 Quinoline-Steroid Hormone Hybrids for ER-α Photodegradation 3.2 Fullerene-Carbohydrate Hybrids for HIV-1 Protease Photodegradation 3.3 Fullerene-Sulfonic Acid Hybrid for Amyloid β Photodegradation 4 Carbohydrate-Photodegrading Organic Molecules 4.1 Small Organic Molecules for Oligosaccharide Photodegradation 4.2 Anthraquinone-Lectin Hybrids for Oligosaccharide Photodegradation 4.3 Anthraquinone-Boronic Acid Hybrids for Oligosaccharide Photodegradation 5 Conclusions
AB - We developed chemical methods for target-selective photodegradation of various biomacromolecules, including DNA, proteins, and carbohydrates. The DNA intercalator-carbohydrate moiety, without the enediyne structure found in the enediyne antibiotic neocarzinostatin chromophore, selectively degrades duplex DNA at guanine (G) nucleotides upon photoirradiation. Based on this finding, we designed and synthesized several artificial DNA intercalator-carbohydrate hybrids that can be photoactivated. Among them, several quinoxaline-carbohydrate hybrids were found to photodegrade duplex DNA at the G on the 5 side of 5-GG-3 sites. For protein degradation, we designed and synthesized several 2-phenylquinoline-steroid hormone hybrids and a porphyrin derivative, both of which selectively photodegrade the transcription factor estrogen receptor-α. In addition, we designed and synthesized fullerene-sugar and fullerene-sulfonic acid hybrids that selectively photodegrade HIV-1 protease and amyloid β, respectively. For carbohydrate degradation, we designed and synthesized anthraquinone-lectin hybrids and anthraquinone- and fullerene-boronic acid hybrids for selective photodegradation of target oligosaccharides having affinity for the lectin or boronic acid moiety of the hybrids. Furthermore, we successfully demonstrated practical uses for these light-activatable and molecular-targeted (LAMTA) molecules for controlling the function of DNA, proteins, and carbohydrates both in glass vessels and in cells. 1 Introduction 2 DNA Photodegrading Organic Molecules 2.1 DNA Intercalator-Carbohydrate Hybrids 2.2 Neocarzinostatin DNA Intercalator- Carbohydrate Hybrids for DNA Photodegradation 2.3 Quinoxaline-Carbohydrate Hybrids for DNA Photodegradation 3 Protein Photodegrading Organic Molecules 3.1 Quinoline-Steroid Hormone Hybrids for ER-α Photodegradation 3.2 Fullerene-Carbohydrate Hybrids for HIV-1 Protease Photodegradation 3.3 Fullerene-Sulfonic Acid Hybrid for Amyloid β Photodegradation 4 Carbohydrate-Photodegrading Organic Molecules 4.1 Small Organic Molecules for Oligosaccharide Photodegradation 4.2 Anthraquinone-Lectin Hybrids for Oligosaccharide Photodegradation 4.3 Anthraquinone-Boronic Acid Hybrids for Oligosaccharide Photodegradation 5 Conclusions
KW - DNA
KW - carbohydrate
KW - photodegradation
KW - protein
KW - synthetic chemical biology
UR - http://www.scopus.com/inward/record.url?scp=84864500146&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84864500146&partnerID=8YFLogxK
U2 - 10.1055/s-0032-1316639
DO - 10.1055/s-0032-1316639
M3 - Article
AN - SCOPUS:84864500146
SN - 0936-5214
VL - 23
SP - 2025
EP - 2052
JO - Synlett
JF - Synlett
IS - 14
ER -