Crystal Structure of Bright Fluorescent Protein BrUSLEE with Subnanosecond Fluorescence Lifetime; Electric and Dynamic Properties.

The rapid development of new microscopy techniques for cell biology has exposed the need for genetically encoded fluorescent tags with special properties. Fluorescent biomarkers of the same color and spectral range and different fluorescent lifetimes (FLs) became useful for fluorescent lifetime image microscopy (FLIM). One such tag, the green fluorescent protein BrUSLEE (Bright Ultimately Short Lifetime Enhanced Emitter), having an extremely short subnanosecond component of fluorescence lifetime (FL~0.66 ns) and exceptional fluorescence brightness, was designed for FLIM experiments. Here, we present the X-ray structure and discuss the structure-functional relations of BrUSLEE. Its development from the EGFP (enhanced green fluorescent proteins) precursor (FL~2.83 ns) resulted in a change of the chromophore microenvironment due to a significant alteration in the side chain conformations. To get further insight into molecular details explaining the observed differences in the photophysical properties of these proteins, we studied their structural, dynamic, and electric properties by all-atom molecular-dynamics simulations in an aqueous solution. It has been shown that compared to BrUSLEE, the mobility of the chromophore in the EGFP is noticeably limited by nonbonded interactions (mainly H-bonds) with the neighboring residues.

Structure of the green fluorescent protein NowGFP with an anionic tryptophan-based chromophore.

A green-emitting fluorescent variant, NowGFP, with a tryptophan-based chromophore (Thr65-Trp66-Gly67) was recently developed from the cyan mCerulean by introducing 18 point mutations. NowGFP is characterized by bright green fluorescence at physiological and higher pH and by weak cyan fluorescence at low pH. Illumination with blue light induces irreversible photoconversion of NowGFP from a green-emitting to a cyan-emitting form. Here, the X-ray structures of intact NowGFP at pH 9.0 and pH 4.8 and of its photoconverted variant, NowGFP_conv, are reported at 1.35, 1.18 and 2.5 Šresolution, respectively. The structure of NowGFP at pH 9.0 suggests the anionic state of Trp66 of the chromophore to be the primary cause of its green fluorescence. At both examined pH values Trp66 predominantly adopted a cis conformation; only ∼ 20% of the trans conformation was observed at pH 4.8. It was shown that Lys61, which adopts two distinct pH-dependent conformations, is a key residue playing a central role in chromophore ionization. At high pH the side chain of Lys61 forms two hydrogen bonds, one to the indole N atom of Trp66 and the other to the carboxyl group of the catalytic Glu222, enabling an indirect noncovalent connection between them that in turn promotes Trp66 deprotonation. At low pH, the side chain of Lys61 is directed away from Trp66 and forms a hydrogen bond to Gln207. It has been shown that photoconversion of NowGFP is accompanied by decomposition of Lys61, with a predominant cleavage of its side chain at the C(γ)-C(δ) bond. Lys61, Glu222, Thr203 and Ser205 form a local hydrogen-bond network connected to the indole ring of the chromophore Trp66; mutation of any of these residues dramatically affects the spectral properties of NowGFP. On the other hand, an Ala150Val replacement in the vicinity of the chromophore indole ring resulted in a new advanced variant with a 2.5-fold improved photostability.

Structural evidence for a dehydrated intermediate in green fluorescent protein chromophore biosynthesis.

The acGFPL is the first-identified member of a novel, colorless and non-fluorescent group of green fluorescent protein (GFP)-like proteins. Its mutant aceGFP, with Gly replacing the invariant catalytic Glu-222, demonstrates a relatively fast maturation rate and bright green fluorescence (lambda(ex) = 480 nm, lambda(em) = 505 nm). The reverse G222E single mutation in aceGFP results in the immature, colorless variant aceGFP-G222E, which undergoes irreversible photoconversion to a green fluorescent state under UV light exposure. Here we present a high resolution crystallographic study of aceGFP and aceGFP-G222E in the immature and UV-photoconverted states. A unique and striking feature of the colorless aceGFP-G222E structure is the chromophore in the trapped intermediate state, where cyclization of the protein backbone has occurred, but Tyr-66 still stays in the native, non-oxidized form, with C(alpha) and C(beta) atoms in the sp(3) hybridization. This experimentally observed immature aceGFP-G222E structure, characterized by the non-coplanar arrangement of the imidazolone and phenolic rings, has been attributed to one of the intermediate states in the GFP chromophore biosynthesis. The UV irradiation (lambda = 250-300 nm) of aceGFP-G222E drives the chromophore maturation further to a green fluorescent state, characterized by the conventional coplanar bicyclic structure with the oxidized double Tyr-66 C(alpha)=C(beta) bond and the conjugated system of pi-electrons. Structure-based site-directed mutagenesis has revealed a critical role of the proximal Tyr-220 in the observed effects. In particular, an alternative reaction pathway via Tyr-220 rather than conventional wild type Glu-222 has been proposed for aceGFP maturation.

Kinetic modeling as a tool to integrate multilevel dynamic experimental data.

The metabolic networks are the most well-studied biochemical systems, with an abundance of in vitro and in vivo data available for quantitative estimation of its kinetic parameters. In this chapter, we present our approach to developing mathematical description of metabolic pathways. The model-based integration of reaction kinetics and the utilization of different types of experimental data including temporal dependencies have been described in detail. Software package DBSolve7 which allows us to develop kinetic model of the biochemical system and integrate experimental data has been presented.