Heme symmetry, vibronic structure, and dynamics in heme proteins: ferrous nicotinate horse myoglobin and soybean leghemoglobin.

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RESEARCH PRODUCT

Heme symmetry, vibronic structure, and dynamics in heme proteins: ferrous nicotinate horse myoglobin and soybean leghemoglobin.

Alberto Boffi Maurizio Leone Antonio Cupane Vincenzo Sanfratello

subject

Hemeproteins Hemeprotein Biophysics Heme Photochemistry Biochemistry Vibration Molecular electronic transition Spectral line Biomaterials chemistry.chemical_compound Animals Ferrous Compounds Horses Heme Myoglobin Protein dynamics Organic Chemistry Nicotinic Acids Temperature General Medicine Protein Structure Tertiary Leghemoglobin Vibronic coupling Myoglobin chemistry Spectrophotometry Molecular vibration Soybeans

description

We report the visible and Soret absorption bands, down to cryogenic temperatures, of the ferrous nicotinate adducts of native and deuteroheme reconstituted horse heart myoglobin in comparison with soybean leghemoglobin-a. The band profile in the visible region is analyzed in terms of vibronic coupling of the heme normal modes to the electronic transition in the framework of the Herzberg–Teller approximation. This theoretical approach makes use of the crude Born–Oppenheimer states and therefore neglects the mixing between electronic and vibrational coordinates; however, it takes into account the vibronic nature of the visible absorption bands and allows an estimate of the vibronic side bands for both Condon and non-Condon vibrational modes. In this framework, an x − y splitting of the Q transition for native and deuteroheme reconstituted horse myoglobin is clearly assessed and attributed to electronic perturbations that, in turn, are caused by a reduction of the typical D4h symmetry of the system due to heme distortions of B1g-type symmetry and/or to an x − y asymmetric position of the nicotinate ring; in deuteroheme reconstituted horse myoglobin the asymmetric heme peripheral substituents add to the above effect(s). On the contrary, in leghemoglobin-a no spectral splitting upon nicotinate binding is observed, pointing to a planar heme configuration in which only distortions of A1g-type symmetry are effective and to which the nicotinate ring is bound in an x − y symmetric position. The local dynamic properties of the heme pocket of the three proteins are investigated through the temperature dependence of spectral line broadening. Leghemoglobin-a behaves as a softer matrix with respect to horse myoglobin, thus validating the hypothesis of a looser heme pocket conformation in the former protein, which allows a nondistorted heme configuration and a symmetric binding of the bulky nicotinate ligand. © 2000 John Wiley & Sons, Inc. Biopolymers (Biospectroscopy) 57: 291–305, 2000

year	journal	country	edition	language
2000-08-25	Biopolymers

https://pubmed.ncbi.nlm.nih.gov/10958321