Lyophilization and enhanced stability of fluorescent protein nanoparticles

Protein nanoparticles (PNPs) that are nanostructured biomaterials with intrinsic biological function have been widely employed as three-dimensional nanobiomaterials for sensitive bioassays, MRI contrast, semiconductor devices, template for hybrid materials, etc., and stable and long-term maintenance of PNPs seems to be of crucial importance. We evaluated the stability of PNPs and the efficacy of lyophilization for the long-term stability of PNPs, especially using green fluorescent protein nanoparticles (gFPNPs) as a model PNP. Fluorescence intensities and TEM images of gFPNPs were analyzed to monitor their functional and structural stabilities. Unlike the green fluorescent protein monomers (eGFP) that were gradually inactivated in aqueous solution, gFPNP in the same aqueous solution retained the initial fluorescence activity and spherical nanoparticle structure even for 2 weeks at 4 °C. To ensure stable and long-term maintenance of gFPNPs, gFPNPs in aqueous solution were converted to the dried solid forms through lyophilization. It is notable that fluorescence activity and nanoparticle structure of gFPNPs that were lyophilized with both Tween 80 and sucrose were very stably maintained even for 10 weeks at various storage temperatures (−20 °C, 4 °C, 25 °C, and 37 °C). During the period of 10 weeks, the fluorescence of gFPNP was always more than 80% level of initial fluorescence at a wide range of temperature. Although this stability study was focused on gFPNPs, the developed optimal lyophilization conditions for gFPNPs can be applied in general to stable and long-term maintenance of many other PNP-derived biomaterials.     

The role of quarternary structure in fluorescent protein stability

The stability of fluorescent proteins (FPs) is of great importance for their use as reporters in studies of gene expression, protein dynamics and localization in cell. A comparative analysis of conformational stability of fluorescent proteins, having different association state was done. The list of studied proteins includes EGFP (monomer of green fluorescent protein, GFP), zFP506 (tetramer GFP), mRFP1 and "dimer2" (monomer and dimmer of red fluorescent protein), DsRed1 (red tetramer). The character of fluorescence intensity changes induced by guanidine hydrochloride (GdnHCl) of these proteins differs significantly. Green tetramer zFP506 has been shown to be more stable than green monomer EGFP, red dimmer "dimer2" has been shown to be less stable than red tetramer DsRed1, while red monomer mRFP1 has been shown to be practically as stable as tetramer DsRedl. It is concluded that the quaternary structure, being an important stabilizing factor, does not represent the only circumstance dictating the dramatic variations between fluorescent proteins in their conformational stability.     

The stability of the TIM-barrel domain of a psychrophilic chitinase

Chitinase 60 from the psychrophilic bacterium Moritella marina (MmChi60) is a four-domain protein whose structure revealed flexible hinge regions between the domains, yielding conformations in solution that range from fully extended to compact. The catalytic domain is a shallow-grooved TIM-barrel. Heat-induced denaturation experiments of the wild-type and mutants resulting from the deletions of the two-Ig-like domains and the chitin binding domain reveal calorimetric profiles that are consistent with non-collaborative thermal unfolding of the individual domains, a property that must be associated to the “hinge-regions”. The calorimetric measurements of the (β/α)₈ catalytic domain reveal that the thermal unfolding is a slow-relaxation transition exhibiting a stable, partially structured intermediate state. Circular dichroism provides evidence that the intermediate exhibits features of a molten globule i.e., loss of tertiary structure while maintaining the secondary structural elements of the native. GdnHCl-induced denaturation studies of the TIM-barrel demonstrate an extraordinarily high resistance to the denaturant. Slow-relaxation kinetics characterize the unfolding with equilibration times exceeding six days, a property that is for the first time observed for a psychrophilic TIM barrel. On the other hand, the thermodynamic stability is ΔG=6.75±1.3 kcal/mol, considerably lower than for structural-insertions-containing barrels. The mutant E153Q used for the crystallographic studies of MmChi60 complexes with NAG ligands has a much lower stability than the wild-type.     

A green-emitting fluorescent protein from Galaxeidae coral and its monomeric version for use in fluorescent labeling

We have cloned a gene which encodes a fluorescent protein from the stony coral, Galaxeidae. This protein absorbs light maximally at 492 nm and emits green light at 505 nm, and as a result, we have designated it "Azami-Green (AG)." Despite sharing a similar spectral profile with enhanced green fluorescent protein (EGFP) (Clontech), the most popular variant of the Aequorea victoria green fluorescent protein, the identity between these two proteins at the amino acid level is only 5.7%. However, since AG has a high extinction coefficient, fluorescence quantum yield, and acid stability, it produces brighter green fluorescence in cultured cells than EGFP. Similar to other fluorescent proteins isolated from coral animals, AG forms a tight tetrameric complex, resulting in poor labeling of subcellular structures such as the plasma membrane and mitochondria. We have converted tetrameric AG into a monomeric form by the introduction of three amino acid substitutions, which were recently reported to be effective for monomerizing the red fluorescent protein from Discosoma coral (DsRed, Clontech). The resultant monomeric AG allowed for efficient fluorescent labeling of all of the subcellular structures and proteins tested while retaining nearly all of the brightness of the original tetrameric form. Thus, monomeric AG is a useful monomeric green-emitting fluorescent protein comparable to EGFP.     

Membrane curvature affects the stability and folding kinetics of bacteriorhodopsin

Biological membrane is crucial for the function, stability and folding of membrane proteins. By studying the stability and folding kinetics of bacteriorhodopsin (bR) in lipid vesicles with different sizes, here we report the influence of membrane curvature (vesicle size) on the stability and folding kinetics of bR. The results show that both the stability and folding kinetics of bR can be significantly changed when reconstituted into mimic membranes with different curvatures. The stability of bR decreases and unfolding rate of bR increases with the growth of vesicle size, i.e. decrease of membrane curvature. Our results suggest that it is possible to regulate the properties of membrane proteins by changing the curvature of membranes.     

A study on the effect of surface lysine to arginine mutagenesis on protein stability and structure using green fluorescent protein

Two positively charged basic amino acids, arginine and lysine, are mostly exposed to protein surface, and play important roles in protein stability by forming electrostatic interactions. In particular, the guanidinium group of arginine allows interactions in three possible directions, which enables arginine to form a larger number of electrostatic interactions compared to lysine. The higher pKa of the basic residue in arginine may also generate more stable ionic interactions than lysine. This paper reports an investigation whether the advantageous properties of arginine over lysine can be utilized to enhance protein stability. A variant of green fluorescent protein (GFP) was created by mutating the maximum possible number of lysine residues on the surface to arginines while retaining the activity. When the stability of the variant was examined under a range of denaturing conditions, the variant was relatively more stable compared to control GFP in the presence of chemical denaturants such as urea, alkaline pH and ionic detergents, but the thermal stability of the protein was not changed. The modeled structure of the variant indicated putative new salt bridges and hydrogen bond interactions that help improve the rigidity of the protein against different chemical denaturants. Structural analyses of the electrostatic interactions also confirmed that the geometric properties of the guanidinium group in arginine had such effects. On the other hand, the altered electrostatic interactions induced by the mutagenesis of surface lysines to arginines adversely affected protein folding, which decreased the productivity of the functional form of the variant. These results suggest that the surface lysine mutagenesis to arginines can be considered one of the parameters in protein stability engineering.     

The effect of ADF/cofilin and profilin on the dynamics of monomeric actin

The main goal of the work was to uncover the dynamical changes in actin induced by the binding of cofilin and profilin. The change in the structure and flexibility of the small domain and its function in the thermodynamic stability of the actin monomer were examined with fluorescence spectroscopy and differential scanning calorimetry (DSC). The structure around the C-terminus of actin is slightly affected by the presence of cofilin and profilin. Temperature dependent fluorescence resonance energy transfer measurements indicated that both actin binding proteins decreased the flexibility of the protein matrix between the subdomains 1 and 2. Time resolved anisotropy decay measurements supported the idea that cofilin and profilin changed similarly the dynamics around the fluorescently labeled Cys-374 and Lys-61 residues in subdomains 1 and 2, respectively. DSC experiments indicated that the thermodynamic stability of actin increased by cofilin and decreased in the presence of profilin. Based on the information obtained it is possible to conclude that while the small domain of actin acts uniformly in the presence of cofilin and profilin the overall stability of actin changes differently in the presence of the studied actin binding proteins. The results support the idea that the small domain of actin behaves as a rigid unit during the opening and closing of the nucleotide binding pocket in the presence of profilin and cofilin as well. The structural arrangement of the nucleotide binding cleft mainly influences the global stability of actin while the dynamics of the different segments can change autonomously.     

Improved monomeric red, orange and yellow fluorescent proteins derived from Discosoma sp. red fluorescent protein

Fluorescent proteins are genetically encoded, easily imaged reporters crucial in biology and biotechnology. When a protein is tagged by fusion to a fluorescent protein, interactions between fluorescent proteins can undesirably disturb targeting or function. Unfortunately, all wild-type yellow-to-red fluorescent proteins reported so far are obligately tetrameric and often toxic or disruptive. The first true monomer was mRFP1, derived from the Discosoma sp. fluorescent protein "DsRed" by directed evolution first to increase the speed of maturation, then to break each subunit interface while restoring fluorescence, which cumulatively required 33 substitutions. Although mRFP1 has already proven widely useful, several properties could bear improvement and more colors would be welcome. We report the next generation of monomers. The latest red version matures more completely, is more tolerant of N-terminal fusions and is over tenfold more photostable than mRFP1. Three monomers with distinguishable hues from yellow-orange to red-orange have higher quantum efficiencies.     

Biological activities and spectroscopic properties of chromophoric and fluorescent analogs of adenine nucleoside and nucleotides, 2′,3′-O-(2,4,6-trinitrocyclohexadienylidene) adenosine derivatives

The ribose-modified chromophoric and fluorescent analog of ATP 2′,3′-O-(2,4,6-trinitrocyclohexadienylidene) adenosine 5′-triphosphate (TNP-ATP) has been synthesized previously (Hiratsuka, T., and Uchida, K. (1973) Biochim. Biophys. Acta 320, 635–647 and Hiratsuka, T. (1976) Biochim. Biophys. Acta 453, 293–297). In the present study, four TNP-derivatives of ATP, ADP, AMP and adenosine were synthesized and compared for several chemical, spectral and enzymatic properties. Their visible absorption and fluorescent properties were found to be quite similar. Visible absorption and fluorescence spectra of TNP-derivatives were sensitive to solvent polarity. TNP-adenosine and TNP-AMP showed considerable substrate activities with adenosine deaminase and alkaline phosphatase, respectively. TNP-ATP proved to be an excellent substitute for ATP in adenylate kinase and myosin ATPase systems. The results indicate that these analogs are useful as chromophoric and fluorescent probes for hydrophobic regions in adenine nucleoside and nucleotide requiring enzymes.     

Molecular dynamics simulation of human interleukin-4: comparison with NMR data and effect of pH,counterions and force field on tertiary structure stability

The human protein interleukin-4 (IL-4) has been simulated at two different pH values 2 and 6, with different amounts of counterions present in the aqueous solution, and with two different force-field parameter sets using molecular dynamics simulation with the aim of validation of force field and simulation set-up by comparison to experimental nuclear magnetic resonance data, such as proton–proton nuclear Overhauser effect (NOE) distance bounds, ³ J(HN,HC_α) coupling constants and backbone N–H order parameters. Thirteen simulations varying in the length from 3 to 7 ns are compared.

At pH 6 both force-field parameter sets used do largely reproduce the NOE's and order parameters, the GROMOS 45A3 set slightly better than the GROMOS 53A6 set. ³ J values predicted from the simulation agree less well with experimental values. At pH 2 the protein unfolds, unless counterions are explicitly present in the system, but even then the agreement with experiment is worse than at pH 6. When simulating a highly charged protein, such as IL-4 at pH 2, the inclusion of counterions in the simulation seems mandatory.     

绿色荧光蛋白及其应用

随着对绿色荧光蛋白(green fluorescent protein,GFP)研究的不断深入,人们对其结构、荧光产生机理等已有较为全面的认识。近年来利用GFP及其它荧光蛋白(FPs)发展了诸如荧光互补技术(FC)、荧光共振能量转移技术(FRET)和超分辨成像(super-resolution imaging)等一系列新技术,极大地促进了生物学、医药科学的研究。主要介绍了荧光蛋白的结构,荧光产生的机理,不同类型的荧光蛋白和基于荧光蛋白产生的新技术等方面的最新研究进展。     

异源基因α1,3半乳糖转移酶与增强型绿色荧光蛋白融合对荧光蛋白表达的影响

目的 研究异源(猪)基因α1,3半乳糖转移酶(3GT)与增强型绿色荧光蛋白(EGFP)基因形成的融合蛋白对其荧光表达量的影响.方法 BamHI,EcoRI酶切pcDNA3.1-α1,3GT重组载体后,回收含α1,3GT的片段,与BamHI、EcoRI酶切回收的pEGFP-N1载体连接,并酶切、测序鉴定重组真核表达载体p...     

Virus capping on mycoplasma cells and its effect on membrane structure

The capping of mycoplasmavirus L3 on the surface of Acholeplasma laidlawii was investigated. In electron microscope studies we observed a reduced capping after treatment of the host cell with energy-blocking agents. Other drugs inhibiting ligand capping on eucariotic cells had no effect. Changes in membrane structure after virus adsorption were observed spectroscopically using the excimer fluorescence technique. The results are interpreted in terms of a lipid-protein phase separation in connection with virus capping.     

Effect of metal ion substitutions in anticoagulation factor I from the venom of Agkistrodon acutus on the binding of activated coagulation factor X and on structural stability

Anticoagulation factor I (ACF I) isolated from the venom of Agkistrodon acutus is an activated coagulation factor X (FXa)-binding protein that binds in a Ca²⁺-dependent fashion with marked anticoagulant activity. The thermodynamics of the binding of alkaline earth metal ions to ACF I and the effects of alkaline earth metal ions on the guanidine hydrochloride (GdnHCl)-induced unfolding of ACF I and the binding of ACF I to FXa were studied by isothermal titration calorimetry, fluorescence, circular dichroism, and surface plasmon resonance, respectively. The results indicate that the ionic radii of the cations occupying Ca²⁺-binding sites in ACF I crucially affect the binding affinity of ACF I for alkaline earth metal ions as well as the structural stability of ACF I against GdnHCl denaturation. Sr²⁺ and Ba²⁺, with ionic radii larger than the ionic radius of Ca²⁺, can bind to Ca²⁺-free ACF I (apo-ACF I), while Mg²⁺, with an ionic radius smaller than that of Ca²⁺, shows significantly low affinity for the binding to apo-ACF I. All bindings of Ca²⁺, Sr²⁺, and Ba²⁺ ions in two sites of ACF I are mainly enthalpy-driven and the entropy is unfavorable for them. Sr²⁺-stabilized ACF I exhibits slightly lower resistance to GdnHCl denaturation than Ca²⁺–ACF I, while Ba²⁺-stabilized ACF I exhibits much lower resistance to GdnHCl denaturation than Ca²⁺–ACF I. Mg²⁺ and Sr²⁺, with ionic radii close to that of Ca²⁺, can bind to FXa and therefore also induce the binding of ACF I to FXa, whereas Ba²⁺, with a much larger ionic radius than Ca²⁺, cannot support the binding of ACF I with FXa. Our observations suggest that bindings of Ca²⁺, Sr²⁺, and Ba²⁺ ions in two sites of ACF I increase the structural stability of ACF I, but these bindings are not essential for the binding of ACF I with FXa, and that the binding of Mg²⁺, Ca²⁺, and Sr²⁺ ions to FXa may be essential for the recognition between FXa and ACF I.     

The effect of carbohydrate on the structure and stability of erythropoietin.

Erythropoietin is a glycoprotein hormone that stimulates the maturation of late erythroid progenitor cells. It has three N-linked and one O-linked carbohydrates which play an important role in the biosynthesis and biological activities of the protein. To determine the role the carbohydrate might have in maintaining the conformational stability of the protein, the protein expressed in mammalian cells (fully glycosylated), the asialo mammalian-expressed protein, and the protein expressed in Escherichia coli (no carbohydrate) were compared for their stability to guanidine HCl, pH, and temperature. Circular dichroism was used to follow protein unfolding. Both the intact and asialo mammalian-expressed proteins unfolded with a cooperative transition in guanidine HCl, with a midpoint at 1.75 M guanidine HCl. The E. coli-expressed material unfolded with a midpoint of 1.2 M guanidine HCl, and a delta G of unfolding which was 1.4 kcal/mol less than that of the two glycosylated molecules. The E. coli-derived protein was also significantly less stable to pH-induced conformational changes, showing a cooperative transition in 35% glycerol with a midpoint at pH 4.4, while both the intact and asialo mammalian-expressed molecules had a transition midpoint of pH 3.75 in the absence of glycerol, and approximately pH 3 in the presence of 35% glycerol. The E. coli-expressed molecule unfolded and precipitated upon heating to 44 degrees C, while the asialo and intact mammalian-expressed proteins remained soluble, with a Tm of 56 degrees C. From these experiments, the carbohydrate appears to play a critical role in stabilizing the erythropoietin molecule to denaturing conditions, and this increased stability does not depend on the presence of sialic acid.     

Understanding the role of Arg96 in structure and stability of green fluorescent protein

Arg96 is a highly conservative residue known to catalyze spontaneous green fluorescent protein (GFP) chromophore biosynthesis. To understand a role of Arg96 in conformational stability and structural behavior of EGFP, the properties of a series of the EGFP mutants bearing substitutions at this position were studied using circular dichroism, steady state fluorescence spectroscopy, fluorescence lifetime, kinetics and equilibrium unfolding analysis, and acrylamide-induced fluorescence quenching. During the protein production and purification, high yield was achieved for EGFP/Arg96Cys variant, whereas EGFP/Arg96Ser and EGFP/Arg96Ala were characterized by essentially lower yields and no protein was produced when Arg96 was substituted by Gly. We have also shown that only EGFP/Arg96Cys possessed relatively fast chromophore maturation, whereas it took EGFP/Arg96Ser and EGFP/Arg96Ala about a year to develop a noticeable green fluorescence. The intensity of the characteristic green fluorescence measured for the EGFP/Arg96Cys and EGFP/Arg96Ser (or EGFP/Arg96Ala) was 5- and 50-times lower than that of the nonmodified EGFP. Intriguingly, EGFP/Arg96Cys was shown to be more stable than EGFP toward the GdmCl-induced unfolding both in kinetics and in the quasi-equilibrium experiments. In comparison with EGFP, tryptophan residues of EGFP/Arg96Cys were more accessible to the solvent. These data taken together suggest that besides established earlier crucial catalytic role, Arg96 is important for the overall folding and conformational stability of GFP.     

The secondary structure of histone IV and its stability.

The secondary structure within histone IV and its fragments obtained by cyanogen bromide (CNBr) and cleavage at Met 84 has been examined by circular dichroism and spectophotometric pH titration measurements. These studies have confirmed the existence of stable secondary structure within the C-terminal fragment of histone IV (C-peptide which can be perturbed only by 6M urea at pH greater than 8 or 8 M guanidine-HCL. In contrast, the N-terminal fragment (N-peptide) appears to lack significant secondary structure at low ionic strengths but acquires approximately 15% betasheet conformation and 5% alpha-helix upon aggregation at ionic strengths larger than or equal to 0.4. The rates of nitration of the N- and C-peptides by tetranitromethane (TNM) have also been measured as a function of ionic strengths. Under comparable conditions, the rate constant for nitration of the N-peptide was found to be about six times greater than that for the C-peptide, further evidence in support of the presence of stable secondary structure within the C-terminal region of histone IV. After binding these histone IV fragments to DNA, however, the nitration reaction rate constants for the N- and C-peptide in the bound form are found to be 2% and 27% of the corresponding free peptides. Reconstituted nucleohistone IV is about 10% as reactive to TNM as histone IV at comparable ionic strength.     

Citrate and phosphate influence on green fluorescent protein thermal stability

Protein structure and function can be regulated by no specific interactions, such as ionic interactions in the presence of salts. Green fluorescent protein (GFP) shows remarkable structural stability and high fluorescence; its stability can be directly related to its fluorescence output, among other characteristics. GFP is stable under increasing temperatures, and its thermal denaturation is highly reproducible. The aim of this study was to evaluate the thermal stability of GFP in the presence of different salts at several concentrations and exposed to constant temperatures, in a range of 70–95°C. Thermal stability was expressed in decimal reduction time. It was observed that the D‐values obtained were higher in the presence of citrate and phosphate, when compared with that obtained in their absence, indicating that these salts stabilized the protein against thermal denaturation. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2011     

The effect of a side chain-backbone swap on protein stability.

To assess the relative importance of backbone hydrogen bonding (H-bonding) vs. side chain hydrophobicity in protein structural formation, a method called side chain-backbone swap is proposed. Such a method swaps the side chain and backbone portions of certain amino acid residues, such as Asp, Glu, Asn, Gln, Lys, and Arg. Such a swap retains the sequence of a polypeptide and preserves the identity of the backbone linkage. On the other hand, the swap disrupts backbone H-bonding geometry because of the introduction of extra methylene groups into the peptide backbone. In this project, we chose the two-stranded alpha-helical coiled-coil to implement side chain-backbone swap. A pair of 36-residue peptides was designed. The two peptides have identical sequence with four residues in each heptad repeat occupied by glutamyl residues. Each glutamic acid was incorporated either as alpha-glutamyl residue (the peptide is denoted as alpha-Glu-36) or as gamma-glutamyl residue (the peptide is denoted as gamma-Glu-36). The inter-conversion between the two peptides constitutes a side chain-backbone swap. Residues constituting the hydrophobic core of the coiled-coil, however, are left unchanged. The peptide pair was characterized by circular dichroism spectroscopy, reversed-phase liquid chromatography (RPLC), and two-dimensional nuclear magnetic resonance (NMR). The results indicate that alpha-Glu-36 is a two-stranded alpha-helical coiled-coil while gamma-Glu-36 lacks stable structural elements. It is concluded that, at least for coiled-coils where hydrophobic interactions are predominantly long-range, local backbone H-bonding is a required for structural formation, consistent with a hierarchic folding mechanism. The methodological implication of side chain-backbone swap is also discussed.