The red fluorescent protein (FP) eqFP611 from the sea anemone Entacmaea quadricolor shows favorable properties for applications as a molecular marker. Like other anthozoan FPs, it forms tetramers at physiological concentrations. The interactions among the monomers, however, are comparatively weak, as inferred from the dissociation into monomers in the presence of sodium dodecyl sulfate (SDS) or at high dilution. Analysis at the single-molecule level revealed that the monomers are highly fluorescent. For application as fusion markers, monomeric FPs are highly desirable. Therefore, we examine the monomer interfaces in the x-ray structure of eqFP611 to provide a basis for the rational design of monomeric variants. The arrangement of the four cans is very similar to that of other green fluorescent protein (GFP-like) proteins such as DsRed and RTMS5. A variety of structural features of the tetrameric interfaces explain the weak subunit interactions in eqFP611. We produce functional dimeric variants by introducing single point mutations in the A/B interface (Thr122Arg, Val124Thr). By contrast, structural manipulations in the A/C interface result in essentially complete loss of fluorescence, suggesting that A/C interfacial interactions play a crucial role in the folding of eqFP611 into its functional form.
The red fluorescent protein eqFP611 shows favorable properties for applications as molecular marker. Its usefulness is, however, limited by its tendency to form tetramers at physiological concentrations. To provide a basis for the rational design of monomeric variants, we examined the monomer interfaces in the x-ray structure of eqFP611. The arrangement of the four ß cans is very similar to that of other GFP-like proteins such as DsRed and RTMS5. In eqFP611, the monomers are linked by comparatively weak interactions, as inferred from the dissociation into monomers in the presence of SDS or at high dilution. Analysis at the single-molecule level revealed that the monomers are highly fluorescent. Some structural features of the tetrameric interfaces explain the weak subunit interactions in eqFP611. Functional dimeric variants could be generated by altering the A/B interface by single point mutations (Thr122Arg, Val124Thr). By contrast, structural manipulations in the A/C interface resulted as yet in essentially complete loss of fluorescence. Presumably, the folding of eqFP611 into its functional form relies on A/C interfacial interactions.
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