CO vibration as a probe of ligand dissociation and transfer in myoglobin

T. Polack; J. P. Ogilvie; S. Franzen; M. H. Vos; M. Joffre; J. L. Martin; A. Alexandrou

CO vibration as a probe of ligand dissociation and transfer in myoglobin

T. Polack
, J. P. Ogilvie
, S. Franzen
, M. H. Vos
, M. Joffre
, J. L. Martin
, A. Alexandrou

INSERM U869

Research output: Contribution to journal › Article › peer-review

Abstract

We report femtosecond visible pump, midinfrared probe, spectrally integrated experiments resolving the dynamics of CO in myoglobin upon photodissociation. Our results show a progressive change in absorption strength of the CO vibrational transition during its transfer from the heme to the docking site, whereas the vibrational frequency change is faster than our time resolution. A phenomenological model gives good qualitative agreement with our data for a time constant of 400 fs for the change in oscillator strength. Density-functional calculations demonstrate that indeed vibrational frequency and absorption strength are not linearly coupled and that the absorption strength varies in a slower manner due to charge transfer from the heme iron to CO.

Original language	English
Pages (from-to)	18102
Number of pages	1
Journal	Physical Review Letters
Volume	93
Issue number	1
Publication status	Published - 2 Jul 2004
Externally published	Yes

Cite this

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abstract = "We report femtosecond visible pump, midinfrared probe, spectrally integrated experiments resolving the dynamics of CO in myoglobin upon photodissociation. Our results show a progressive change in absorption strength of the CO vibrational transition during its transfer from the heme to the docking site, whereas the vibrational frequency change is faster than our time resolution. A phenomenological model gives good qualitative agreement with our data for a time constant of 400 fs for the change in oscillator strength. Density-functional calculations demonstrate that indeed vibrational frequency and absorption strength are not linearly coupled and that the absorption strength varies in a slower manner due to charge transfer from the heme iron to CO.",

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T1 - CO vibration as a probe of ligand dissociation and transfer in myoglobin

AU - Polack, T.

AU - Ogilvie, J. P.

AU - Franzen, S.

AU - Vos, M. H.

AU - Joffre, M.

AU - Martin, J. L.

AU - Alexandrou, A.

PY - 2004/7/2

Y1 - 2004/7/2

N2 - We report femtosecond visible pump, midinfrared probe, spectrally integrated experiments resolving the dynamics of CO in myoglobin upon photodissociation. Our results show a progressive change in absorption strength of the CO vibrational transition during its transfer from the heme to the docking site, whereas the vibrational frequency change is faster than our time resolution. A phenomenological model gives good qualitative agreement with our data for a time constant of 400 fs for the change in oscillator strength. Density-functional calculations demonstrate that indeed vibrational frequency and absorption strength are not linearly coupled and that the absorption strength varies in a slower manner due to charge transfer from the heme iron to CO.

AB - We report femtosecond visible pump, midinfrared probe, spectrally integrated experiments resolving the dynamics of CO in myoglobin upon photodissociation. Our results show a progressive change in absorption strength of the CO vibrational transition during its transfer from the heme to the docking site, whereas the vibrational frequency change is faster than our time resolution. A phenomenological model gives good qualitative agreement with our data for a time constant of 400 fs for the change in oscillator strength. Density-functional calculations demonstrate that indeed vibrational frequency and absorption strength are not linearly coupled and that the absorption strength varies in a slower manner due to charge transfer from the heme iron to CO.

M3 - Article

C2 - 15324023

AN - SCOPUS:3442887361

SN - 0031-9007

VL - 93

SP - 18102

JO - Physical Review Letters

JF - Physical Review Letters

IS - 1

ER -

CO vibration as a probe of ligand dissociation and transfer in myoglobin

Abstract

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