Mutants of monomeric red fluorescent protein mRFP1 at residue 66: Structure modeling by molecular dynamics and search for correlations with spectral properties

Abstract: Fluorescent proteins are widely used as markers for visualization of processes in intact biological systems. The family of fluorescent proteins includes proteins of various representatives of Coelenterata that are able to absorb light and emit in the visible spectral range. All flu orescent proteins have similar structure represented by 11 strand β barrel with α helix inside, which contains a chromophore in the middle. The chromophore is a het erogroup formed by an autocatalytic posttranslational reaction betw… Show more

“…It was predicted that the volume of the amino acid residue at position 66 can correlate with the optical characteristics of the mutants. The experimental results presented in this Section are consistent with the results of simulations performed by (Khrameeva et al, 2008). For the mutants with non-polar groups at residue 66 (alanine, leucine and phenylalanine) there is no correlation effect.…”

“…The deviations from chromophore coplanarity are responsible for the changes in the optical characteristics for mCherry and mStrawberry (Shu et al, 2006). The interrelation between the optical properties of the monomeric red FPs and the geometry of their chromophores was also confirmed by the molecular dynamics simulations conducted for mRFP1 mutants with single polar amino acid substitutions at position 66 (Khrameeva et al, 2008). The simulations have shown that the substitutions have an influence on the torsion angles in the phenolic and imidazolidine rings of the chromophore as well as on the torsion angles in the regions of connection between these rings and chromophore attachment to -barrel.…”

“…The seven mutants with substitution of the glutamine 66 for the serine (protein mRFP1/Q66S 2 ), cysteine (mRFP1/Q66C), asparagine (mRFP1/Q66N), histidine (mRFP1/Q66H), alanine (mRFP1/Q66A), leucine (mRFP1/Q66L) and phenylalanine (mRFP1/Q66F) have been created. The method for fabrication and purification of proteins is described in (Vrzheshch et al, 2008). All the experiments were performed in a 0.06 M phosphate buffer at a temperature of 25±1 °C.…”

“…7 (c, d)). These radicals, in turn, belong to the protein shell (the -barrel) and are rather rigidly bonded to it (Khrameeva et al, 2008). A change in the geometry of the side radical at position 66 will in this case cause a change in the geometry of the chromophore imidazolidine ring, because the interaction of the chromophore with the glutamine-42 and glutamine-213 through the hydrogen bond network can be distorted and a new bond with glutamate-215 can be formed.…”

Laser Fluorescence Spectroscopy: Application in Determining the Individual Photophysical Parameters of Proteins

“…It was predicted that the volume of the amino acid residue at position 66 can correlate with the optical characteristics of the mutants. The experimental results presented in this Section are consistent with the results of simulations performed by (Khrameeva et al, 2008). For the mutants with non-polar groups at residue 66 (alanine, leucine and phenylalanine) there is no correlation effect.…”

“…The deviations from chromophore coplanarity are responsible for the changes in the optical characteristics for mCherry and mStrawberry (Shu et al, 2006). The interrelation between the optical properties of the monomeric red FPs and the geometry of their chromophores was also confirmed by the molecular dynamics simulations conducted for mRFP1 mutants with single polar amino acid substitutions at position 66 (Khrameeva et al, 2008). The simulations have shown that the substitutions have an influence on the torsion angles in the phenolic and imidazolidine rings of the chromophore as well as on the torsion angles in the regions of connection between these rings and chromophore attachment to -barrel.…”

“…The seven mutants with substitution of the glutamine 66 for the serine (protein mRFP1/Q66S 2 ), cysteine (mRFP1/Q66C), asparagine (mRFP1/Q66N), histidine (mRFP1/Q66H), alanine (mRFP1/Q66A), leucine (mRFP1/Q66L) and phenylalanine (mRFP1/Q66F) have been created. The method for fabrication and purification of proteins is described in (Vrzheshch et al, 2008). All the experiments were performed in a 0.06 M phosphate buffer at a temperature of 25±1 °C.…”

“…7 (c, d)). These radicals, in turn, belong to the protein shell (the -barrel) and are rather rigidly bonded to it (Khrameeva et al, 2008). A change in the geometry of the side radical at position 66 will in this case cause a change in the geometry of the chromophore imidazolidine ring, because the interaction of the chromophore with the glutamine-42 and glutamine-213 through the hydrogen bond network can be distorted and a new bond with glutamate-215 can be formed.…”

Laser Fluorescence Spectroscopy: Application in Determining the Individual Photophysical Parameters of Proteins

“…The excitation and emission wavelengths of REDantibody were determined to be 584nm and 607nm respectively (as shown in Figure 5A), are identical to that of mRFP (Campbell et al, 2002; Khrameeva et al, 2008), confirming that the fusing immunoglobulin domains to both ends of a FP did not compromise the fluorescent properties. Moreover, it may be possible to detect as little as 9.5 pmoles of REDantibody using a standard fluorometer as shown in figure 5B.…”

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