PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
33780054-0	2021	Low-Spin and High-Spin Perferryl Intermediates in Non-Heme Iron Catalyzed Oxidations of Aliphatic C-H Groups.	Heme	54-58	spindlin 1	Homo sapiens	4-8	
33780054-0	2021	Low-Spin and High-Spin Perferryl Intermediates in Non-Heme Iron Catalyzed Oxidations of Aliphatic C-H Groups.	Heme	54-58	spindlin 1	Homo sapiens	18-22	
27101151-1	2016	Although the interaction of low-spin ferric complexes with nitric oxide has been well studied, examples of stable high-spin ferric nitrosyls (such as those that could be expected to form at typical non-heme iron sites in biology) are extremely rare.	Heme	202-206	spindlin 1	Homo sapiens	119-123	
6277891-2	1982	A relaxation occurring in approximately 100 microseconds involves perturbation of a spin-equilibrium between two folded conformers of the protein with methionine-80 coordinated or dissociated from the heme iron.	Heme	201-205	spindlin 1	Homo sapiens	84-88	
518870-8	1979	There are two possible implications of this result: (1) the iron atom spin state is not the only major factor in the determination of its position with respect to the heme plane or (2) the change with conformation of the protein force exerted by the proximal histidine on the iron atom (for an iron to heme-plane displacement of less than 0.3 A) is less than 50% of that expected from simple models in which this motion is responsible for cooperativity.	Heme	302-306	spindlin 1	Homo sapiens	70-74	
182223-3	1976	The observation of a 630 nm band in quantum mixed-spin heme spectra, and the spin state-dependence of the band intensity, are discussed in the context of the iron-ligand structure for quantum mixed-spin heme inferred from magnetic data.	Heme	55-59	spindlin 1	Homo sapiens	50-54	
182223-3	1976	The observation of a 630 nm band in quantum mixed-spin heme spectra, and the spin state-dependence of the band intensity, are discussed in the context of the iron-ligand structure for quantum mixed-spin heme inferred from magnetic data.	Heme	203-207	spindlin 1	Homo sapiens	50-54	
182223-3	1976	The observation of a 630 nm band in quantum mixed-spin heme spectra, and the spin state-dependence of the band intensity, are discussed in the context of the iron-ligand structure for quantum mixed-spin heme inferred from magnetic data.	Heme	203-207	spindlin 1	Homo sapiens	77-81	
182223-3	1976	The observation of a 630 nm band in quantum mixed-spin heme spectra, and the spin state-dependence of the band intensity, are discussed in the context of the iron-ligand structure for quantum mixed-spin heme inferred from magnetic data.	Heme	203-207	spindlin 1	Homo sapiens	77-81	
28328227-0	2017	Ultrafast Relaxation Dynamics of Photoexcited Heme Model Compounds: Observation of Multiple Electronic Spin States and Vibrational Cooling.	Heme	46-50	spindlin 1	Homo sapiens	103-107	
28328227-8	2017	Thus, the transient absorption spectra of these model compounds reveal the involvement of multiple iron spin states in the electronic relaxation dynamics, which could be an alternative pathway to the ground state beside the vibrational cooling processes and associated with the inherent features of the heme b type.	Heme	303-307	spindlin 1	Homo sapiens	104-108	
732573-0	1978	Spin states of heme proteins by magnetic circular dichroism.	Heme	15-19	spindlin 1	Homo sapiens	0-4	
32841410-0	2020	Spin-inversion mechanisms in O2 binding to a model heme compound: A perspective from nonadiabatic wave packet calculations.	Heme	51-55	spindlin 1	Homo sapiens	0-4	
32841410-1	2020	Spin-inversion dynamics in O2 binding to a model heme complex, which consisted of Fe(II)-porphyrin and imidazole, were studied using nonadiabatic wave packet dynamics calculations.	Heme	49-53	spindlin 1	Homo sapiens	0-4	
31265281-0	2019	Ab Initio Calculations for Spin-Gaps of Non-Heme Iron Complexes.	Heme	44-48	spindlin 1	Homo sapiens	27-31	
28737390-0	2017	Kinetic Isotope Effect Probes the Reactive Spin State, As Well As the Geometric Feature and Constitution of the Transition State during H-Abstraction by Heme Compound II Complexes.	Heme	153-157	spindlin 1	Homo sapiens	43-47	
26000802-7	2015	The results of this study are important to appreciate the role of spin-state changes in ligand binding properties of heme-related models.	Heme	117-121	spindlin 1	Homo sapiens	66-70	
25820781-4	2015	Hemin, prototypical for the heme group in hemoglobin, is used to demonstrate the method, as a representative biomolecule where the spin state of a metal ion affects biological functions.	Heme	28-32	spindlin 1	Homo sapiens	131-135	
17100424-9	2006	Implications of the present work to the theoretical study of heme-containing biological molecules and other spin-related systems are discussed.	Heme	61-65	spindlin 1	Homo sapiens	108-112	
26617311-0	2010	Performance of CASPT2 and DFT for Relative Spin-State Energetics of Heme Models.	Heme	68-72	spindlin 1	Homo sapiens	43-47	
18775958-3	2008	Coordination of cyanide to the met heme formed low-spin complexes.	Heme	35-39	spindlin 1	Homo sapiens	51-55	
16551096-11	2006	Spin density at the A-propionate side chain of heme can occur in the case of incomplete screening but has no major effect on the computed barrier.	Heme	47-51	spindlin 1	Homo sapiens	0-4	
12477933-0	2002	Spin-dependent mechanism for diatomic ligand binding to heme.	Heme	56-60	spindlin 1	Homo sapiens	0-4	
12477933-3	2002	The interaction of all possible spin states of the three common diatomic ligands, CO, NO, and O2, and high-spin heme iron is compared.	Heme	112-116	spindlin 1	Homo sapiens	107-111	
8784177-5	1996	In Mn-depleted PSII membranes the high-spin (S = 2) non-heme iron, enhances the spin-lattice relaxation of Pheo-.	Heme	56-60	spindlin 1	Homo sapiens	39-43	
8784177-5	1996	In Mn-depleted PSII membranes the high-spin (S = 2) non-heme iron, enhances the spin-lattice relaxation of Pheo-.	Heme	56-60	spindlin 1	Homo sapiens	80-84