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Inhibition of DNA restrictive endonucleases by aqueous nanoparticle suspension of methanophosphonate fullerene derivatives and its mechanisms

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ã€Authorã€‘ SONG GaoGuang, YAO Lu, HUANG Cheng, XIE Xin, TAN Xin & YANG XinLin School of Life Science and Technology, Beijing Institute of Technology, Beijing 100081, China

ã€æ‘˜è¦ã€‘ Aqueous nanoparticle suspension of fullerene and its derivatives are currently attracting much attention. To determine the effects of aqueous nanoparticle suspension of a mono-methanophosphonate fullerene and bis-methanophosphonate fullerene (denoted as n-MMPF and n-BMPF, respectively) on the activities of DNA restrictive endonucleases, plasmid pEGFP-N1 was cleaved at a single but differently restrictive site by EcoR I, BamH I, and isozymes Cfr9 I and Xma I, respectively. Both n-MMPF and n-BMPF inhibited the activity of EcoR I, while n-BMPF exhibited stronger inhibition than n-MMPF. Addition of n-BMPF into reaction mixtures inhibited the activities of all the four enzymes, and IC50 values for EcoR I, BamH I, Cfr9 I and Xma I were 4.3, >30, 11.7 and 8.3 Î¼mol/L, respectively. When EcoR I was completely inhibited by n-BMPF, addition of excess amounts of pEGFP-N1 could not produce the product linear plasmid; however, increase of EcoR I amounts antagonized EcoR I inhibition of n-BMPF. Two scavengers of reactive oxygen species (ROS), mannitol and sodium azide at the concentrations of 2-10 mmol/L, did not reverse inhibition of n-BMPF, implying that this inhibition probably is not correlated to ROS. These results suggested that aqueous nano-fullerenes might act as inhibitors of DNA restrictive endonucleases.æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ Aqueous nanoparticle suspension of fullerene and its derivatives are currently attracting much attention. To determine the effects of aqueous nanoparticle suspension of a mono-methanophosphonate fullerene and bis-methanophosphonate fullerene (denoted as n-MMPF and n-BMPF, respectively) on the activities of DNA restrictive endonucleases, plasmid pEGFP-N1 was cleaved at a single but differently restrictive site by EcoR I, BamH I, and isozymes Cfr9 I and Xma I, respectively. Both n-MMPF and n-BMPF inhibited the activity of EcoR I, while n-BMPF exhibited stronger inhibition than n-MMPF. Addition of n-BMPF into reaction mixtures inhibited the activities of all the four enzymes, and IC50 values for EcoR I, BamH I, Cfr9 I and Xma I were 4.3, >30, 11.7 and 8.3 Î¼mol/L, respectively. When EcoR I was completely inhibited by n-BMPF, addition of excess amounts of pEGFP-N1 could not produce the product linear plasmid; however, increase of EcoR I amounts antagonized EcoR I inhibition of n-BMPF. Two scavengers of reactive oxygen species (ROS), mannitol and sodium azide at the concentrations of 2-10 mmol/L, did not reverse inhibition of n-BMPF, implying that this inhibition probably is not correlated to ROS. These results suggested that aqueous nano-fullerenes might act as inhibitors of DNA restrictive endonucleases.æ›´å¤š è¿˜åŽŸ

ã€å…³é”®è¯ã€‘ mono-and bis-methanophosphonate fullereneï¼› aqueous nanoparticle suspensionï¼› DNA restrictive endonucleasesï¼› reactive oxygen speciesï¼›
ã€Key wordsã€‘ mono-and bis-methanophosphonate fullereneï¼› aqueous nanoparticle suspensionï¼› DNA restrictive endonucleasesï¼› reactive oxygen speciesï¼›

ã€åŸºé‡‘ã€‘ Supported by the National Natural Science Foundation of China (Grant No. 20672012);Beijing Natural Science Foundation (Grant No. 20822020)

ã€æ–‡çŒ®å‡ºå¤„ã€‘ Science in China(Series B:Chemistry) ,ä¸å›½ç§‘å¦(Bè¾‘:åŒ–å¦)(è‹±æ–‡ç‰ˆ) , ç¼–è¾‘éƒ¨é‚®ç®± ,2009å¹´05æœŸ

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