PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
16722672-9	2006	At low-temperature, the reaction also proceeds via CH3 + O2 (+ M) --> CH3O2 (+ M); CH3O2 + NO --> CH3O + NO2 and C2H5 + O2 --> C2H5O2; C2H5O2 + NO --> C2H5O + NO2.	Nitrogen Dioxide	171-174	immunoglobulin kappa variable 1D-39	Homo sapiens	119-128	
25619120-6	2015	There were two reasons: (1) pH can influence the flow direction of electrons afforded by NH2OH oxidation; at high pH, electrons were mainly used for combining H+ and O2 (O2+4H++4e-=2H2O), the accumulation of NO2- cannot be a result of denitrification, and a higher DO can get more electrons to prefer NO2- and (2) NH4+ was the prerequisite for NH2OH oxidation, since NH2OH oxidation process was the way to provide electrons for nitrifier denitrification.	Nitrogen Dioxide	208-211	immunoglobulin kappa variable 1D-39	Homo sapiens	166-168	
25619120-6	2015	There were two reasons: (1) pH can influence the flow direction of electrons afforded by NH2OH oxidation; at high pH, electrons were mainly used for combining H+ and O2 (O2+4H++4e-=2H2O), the accumulation of NO2- cannot be a result of denitrification, and a higher DO can get more electrons to prefer NO2- and (2) NH4+ was the prerequisite for NH2OH oxidation, since NH2OH oxidation process was the way to provide electrons for nitrifier denitrification.	Nitrogen Dioxide	208-211	immunoglobulin kappa variable 1D-39	Homo sapiens	170-172	
25619120-6	2015	There were two reasons: (1) pH can influence the flow direction of electrons afforded by NH2OH oxidation; at high pH, electrons were mainly used for combining H+ and O2 (O2+4H++4e-=2H2O), the accumulation of NO2- cannot be a result of denitrification, and a higher DO can get more electrons to prefer NO2- and (2) NH4+ was the prerequisite for NH2OH oxidation, since NH2OH oxidation process was the way to provide electrons for nitrifier denitrification.	Nitrogen Dioxide	301-304	immunoglobulin kappa variable 1D-39	Homo sapiens	166-168	
25619120-6	2015	There were two reasons: (1) pH can influence the flow direction of electrons afforded by NH2OH oxidation; at high pH, electrons were mainly used for combining H+ and O2 (O2+4H++4e-=2H2O), the accumulation of NO2- cannot be a result of denitrification, and a higher DO can get more electrons to prefer NO2- and (2) NH4+ was the prerequisite for NH2OH oxidation, since NH2OH oxidation process was the way to provide electrons for nitrifier denitrification.	Nitrogen Dioxide	301-304	immunoglobulin kappa variable 1D-39	Homo sapiens	170-172	
25458679-0	2014	Experimental study of NO2 reduction in N2/Ar and O2/Ar mixtures by pulsed corona discharge.	Nitrogen Dioxide	22-25	immunoglobulin kappa variable 1D-39	Homo sapiens	49-54