Tetramethylrhodamine dimer formation as a spectroscopic probe of the conformation of Escherichia coli ribosomal protein L7/L12 dimers

Construction of Ultralarge Two-Dimensional Fluorescent Protein Arrays via a Reengineered Rhodamine B-Based Molecular Tool

The self-luminous property of enhanced green fluorescent protein (EGFP) makes it an extremely attractive building block for creating functional biomaterials. A practical challenge in the design of EGFP-based materials, however, stems from the structural and chemical heterogeneity of the EGFP surface. In this study, a maleimide-functionalized rhodamine B molecule (RhG₂M) was designed as a versatile molecular tool to overcome this obstacle. Site-specific modification of an EGFP variant (EGFP-4C) with RhG₂M allowed for the fabrication of a series of well-defined two-dimensional (2D) arrays that span nano- and micrometer scales. Furthermore, the resulting ultralarge 2D EGFP-4C arrays feature both structural uniformity and flexibility, together with the inherent optical properties, making them advanced materials with great potential for practical applications. In addition, this strategy can be further extended into three dimensions and applied to the modular generation of periodic functional materials with more complex structures.

Structural and kinetic basis for the regulation and potentiation of Hsp104 function

Hsp104 provides a valuable model for the many essential proteostatic functions performed by the AAA+ superfamily of protein molecular machines. We developed and used a powerful hydrogen exchange mass spectrometry (HX MS) analysis that can provide positionally resolved information on structure, dynamics, and energetics of the Hsp104 molecular machinery, even during functional cycling. HX MS reveals that the ATPase cycle is rate-limited by ADP release from nucleotide-binding domain 1 (NBD1). The middle domain (MD) serves to regulate Hsp104 activity by slowing ADP release. Mutational potentiation accelerates ADP release, thereby increasing ATPase activity. It reduces time in the open state, thereby decreasing substrate protein loss. During active cycling, Hsp104 transits repeatedly between whole hexamer closed and open states. Under diverse conditions, the shift of open/closed balance can lead to premature substrate loss, normal processing, or the generation of a strong pulling force. HX MS exposes the mechanisms of these functions at near-residue resolution.

Photophysical characterization of interchromophoric interactions between rhodamine dyes conjugated to proteins

Rhodamine dyes in aqueous solution form non-fluorescent dimers with a plane-to-plane stacking geometry (H-dimers). The self-quenching properties of these dimers have been exploited to probe the conformation and dynamics of proteins using a variety of fluorescence approaches that require the interpretation of fluorescence intensities, lifetimes and fluctuations. Here, we report on a systematic study of the photophysical properties of three rhodamine dyes (tetramethylrhodamine, Alexa 488 and Alexa 546) covalently bound to the E. coli sliding clamp (β clamp) with emphasis on the properties of the H-dimers that form when the dimeric protein is labeled with one dye at each side of the dimer interface. Overall, results are consistent with an equilibrium between non-emissive dimers and unstacked monomers that experience efficient dynamic quenching Protein constructs labeled with tetramethylrhodamine show the characteristic features of H-dimers in their absorption spectra and a c.a. 40-fold quenching of fluorescence intensity. The degree of quenching decreases when samples are labeled with a tetramethylrhodamine derivative bearing a six-carbon linker. H-dimers do not form in samples labeled with Alexa 488 and A546, but fluorescence is still quenched in these samples through a dynamic mechanism. These results should help researchers design and interpret fluorescence experiments that take advantage of the properties of rhodamine dimers in protein research.

Development of a range of fluorescent reagentless biosensors for ATP, based on malonyl-coenzyme A synthetase

The range of ATP concentrations that can be measured with a fluorescent reagentless biosensor for ATP has been increased by modulating its affinity for this analyte. The ATP biosensor is an adduct of two tetramethylrhodamines with MatB from Rhodopseudomonas palustris. Mutations were introduced into the binding site to modify ATP binding affinity, while aiming to maintain the concomitant fluorescence signal. Using this signal, the effect of mutations in different parts of the binding site was measured. This mutational analysis revealed three variants in particular, each with a single mutation in the phosphate-binding loop, which had potentially beneficial changes in ATP binding properties but preserving a fluorescence change of ~3-fold on ATP binding. Two variants (T167A and T303A) weakened the binding, changing the dissociation constant from the parent's 6 μM to 123 μM and 42 μM, respectively. Kinetic measurements showed that the effect of these mutations on affinity was by an increase in dissociation rate constants. These variants widen the range of ATP concentration that can be measured readily by this biosensor to >100 μM. In contrast, a third variant, S170A, decreased the dissociation constant of ATP to 3.8 μM and has a fluorescence change of 4.2 on binding ATP. This variant has increased selectivity for ATP over ADP of >200-fold. This had advantages over the parent by increasing sensitivity as well as increasing selectivity during ATP measurements in which ADP is present.

Probing the endocytic pathways of the filamentous bacteriophage in live cells using ratiometric pH fluorescent indicator

Viral nanoparticles have attracted extensive research interests in diverse applications of diagnosis and therapy. In particular, filamentous M13 bacteriophages have shown great potential in biomedical applications. However, its pathways entering into cells still remain unclear, and this greatly hinders its further use as a drug or gene carrier. Here, a ratiometric M13 pH probe is designed by conjugating two fluorescent dyes onto the surface of M13. Since the intensity ratio is not influenced by probe concentration, ion strength, temperature, photobleaching, and optical path length, this ratiometric probe can be used to investigate the intracellular pH map of M13. More importantly, the internalization mechanism of M13 can be elucidated. It is found that this filamentous phage shows great cell-type dependence in interaction with cells and internalization mechanism. The phage tends to be bounded on the cell membrane of only epithelial cells, not endothelial cells. Furthermore, the M13 phage enters into cells through endocytosis with specific mechanism: clathrin-mediated endocytosis and macropinocytosis for HeLa; vesicular transport, clathrin-mediated endocytosis, and macropinocytosis for MCF-7; caveolae-mediated endocytosis for human dermal microvascular endothelial cell (HDMEC). This work provides key notes for cancer diagnosis and therapy based on filamentous bacteriophage, especially for design of pH-sensitive drug delivery systems.

Kinetics study on the HIV-1 ectodomain protein quaternary structure formation reveals coupling of chain folding and self-assembly in the refolding cascade

Entry of HIV-1 into the target cell is mediated by the envelope glycoprotein consisting of noncovalently associated surface subunit gp120 and transmembrane subunit gp41. To form a functional gp41 complex, the protein undergoes hairpin formation and self-assembly. The fusion event can be inhibited by gp41-derived peptides at nanomolar concentration and is highly dependent on the time of addition, implying a role of folding kinetics on the inhibitory action. Oligomerization of the gp41 ectodomain was demonstrated by light scattering measurements. Kinetic study by stopped-flow fluorescence and absorption measurements (i) revealed a multistate folding pathway and stable intermediates; (ii) showed a dissection of fast and slow components for early and late stages of folding, respectively, with 3 orders of magnitude difference in the time scale; (iii) showed the slow process was attributed to misfolding and unzipping of the hairpin; and (iv) showed retardation of the native hairpin formation is assumed to lead to coupling of the correctly registered hairpin and self-assembly. This coupling allows the deduction on the time scale of intrachain folding (0.1-1 s) for the protein. The folding reaction was illustrated by a free energy profile to explain the temporal dichotomy of fast and slow steps of folding as well as effective inhibition by gp41-derived peptide.

Intrinsic stability and oligomerization dynamics of DNA processivity clamps

Sliding clamps are ring-shaped oligomeric proteins that are essential for processive deoxyribonucleic acid replication. Although crystallographic structures of several clamps have been determined, much less is known about clamp structure and dynamics in solution. Here, we characterized the intrinsic solution stability and oligomerization dynamics of the homodimeric Escherichia coli β and the homotrimeric Saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA) clamps using single-molecule approaches. We show that E. coli β is stable in solution as a closed ring at concentrations three orders of magnitude lower than PCNA. The trimeric structure of PCNA results in slow subunit association rates and is largely responsible for the lower solution stability. Despite this large difference, the intrinsic lifetimes of the rings differ by only one order of magnitude. Our results show that the longer lifetime of the E. coli β dimer is due to more prominent electrostatic interactions that stabilize the subunit interfaces.

Measuring how much work the chaperone GroEL can do

Noncovalently "stacked" tetramethylrhodamine (TMR) dimers have been used to both report and perturb the allosteric equilibrium in GroEL. A GroEL mutant (K242C) has been labeled with TMR, close to the peptide-binding site in the apical domain, such that TMR molecules on adjacent subunits are able to form dimers in the T allosteric state. Addition of ATP induces the transition to the R state and the separation of the peptide-binding sites, with concomitant unstacking of the TMR dimers. A statistical analysis of the spectra allowed us to compute the number and orientation of TMR dimers per ring as a function of the average number of TMR molecules per ring. The TMR dimers thus serve as quantitative reporter of the allosteric state of the system. The TMR dimers also serve as a surrogate for substrate protein, substituting in a more homogeneous, quantifiable manner for the heterogeneous intersubunit, intraring, noncovalent cross-links provided by the substrate protein. The characteristic stimulation of the ATPase activity by substrate protein is also mimicked by the TMR dimers. Using an expanded version of the nested cooperativity model, we determine values for the free energy of the TT to TR and TR to RR allosteric equilibria to be 27 ± 11 and 46 ± 2 kJ/mol, respectively. The free energy of unstacking of the TMR dimers was estimated at 2.6 ± 1.0 kJ/mol dimer. These results demonstrate that GroEL can perform work during the T to R transition, supporting the iterative annealing model of chaperonin function.

Metal-directed, chemically tunable assembly of one-, two- and three-dimensional crystalline protein arrays

Proteins represent the most sophisticated building blocks available to an organism and to the laboratory chemist. Yet, in contrast to nearly all other types of molecular building blocks, the designed self-assembly of proteins has largely been inaccessible because of the chemical and structural heterogeneity of protein surfaces. To circumvent the challenge of programming extensive non-covalent interactions to control protein self-assembly, we have previously exploited the directionality and strength of metal coordination interactions to guide the formation of closed, homoligomeric protein assemblies. Here, we extend this strategy to the generation of periodic protein arrays. We show that a monomeric protein with properly oriented coordination motifs on its surface can arrange, on metal binding, into one-dimensional nanotubes and two- or three-dimensional crystalline arrays with dimensions that collectively span nearly the entire nano- and micrometre scale. The assembly of these arrays is tuned predictably by external stimuli, such as metal concentration and pH.

Detecting intramolecular conformational dynamics of single molecules in short distance range with subnanometer sensitivity

Single molecule detection is useful for characterizing nanoscale objects such as biological macromolecules, nanoparticles and nanodevices with nanometer spatial resolution. Fluorescence resonance energy transfer (FRET) is widely used as a single-molecule assay to monitor intramolecular dynamics in the distance range of 3-8 nm. Here we demonstrate that self-quenching of two rhodamine derivatives can be used to detect small conformational dynamics corresponding to subnanometer distance changes in a FRET-insensitive short-range at the single molecule level. A ParM protein mutant labeled with two rhodamines works as a single molecule adenosine 5'-diphosphate (ADP) sensor that has 20 times brighter fluorescence signal in the ADP bound state than the unbound state. Single molecule time trajectories show discrete transitions between fluorescence on and off states that can be directly ascribed to ADP binding and dissociation events. The conformational changes observed with 20:1 contrast are only 0.5 nm in magnitude and are between crystallographic distances of 1.6 and 2.1 nm, demonstrating exquisite sensitivity to short distance scale changes. The systems also allowed us to gain information on the photophysics of self-quenching induced by rhodamine stacking: (1) photobleaching of either of the two rhodamines eliminates quenching of the other rhodamine fluorophore and (2) photobleaching from the highly quenched, stacked state is only 2-fold slower than from the unstacked state.

Determination of the photoluminescence quantum yield of diluted dye solutions in highly scattering media by pulsed photoacoustic spectroscopy

A pulsed photoacoustic system is used to determine the fluorescence quantum yield of diluted dye solutions in highly scattering media. In order to show its accuracy, the quantum yield of Rhodamine 6G in water and ethanol was calculated. The chemical Fuchsin was utilized as a dye reference because the entire excitation energy is converted into nonradiative relaxation processes. The scattering coefficient of the samples was incremented by using spherical silica particles of different sizes and concentrations. The determined mean values in the studied scattering optical density range (0-3 cm(-1)) were 0.95 for ethanol and 0.96 for water. These measurements are in excellent agreement with the best literature values.

Chemical modification of M13 bacteriophage and its application in cancer cell imaging

The M13 bacteriophage has been demonstrated to be a robust scaffold for bionanomaterial development. In this paper, we report on the chemical modifications of three kinds of reactive groups, i.e., the amino groups of lysine residues or N-terminal, the carboxylic acid groups of aspartic acid or glutamic acid residues, and the phenol group of tyrosine residues, on M13 surface. The reactivity of each group was identified through conjugation with small fluorescent molecules. Furthermore, the regioselectivity of each reaction was investigated by HPLC-MS-MS. By optimizing the reaction condition, hundreds of fluorescent moieties could be attached to create a highly fluorescent M13 bacteriophage. In addition, cancer cell targeting motifs such as folic acid could also be conjugated onto the M13 surface. Therefore, dual-modified M13 particles with folic acid and fluorescent molecules were synthesized via the selective modification of two kinds of reactive groups. Such dual-modified M13 particles showed very good binding affinity to human KB cancer cells, which demonstrated the potential applications of M13 bacteriophage in bioimaging and drug delivery.

Optical properties and application of a reactive and bioreducible thiol-containing tetramethylrhodamine dimer

Thiolated dimeric tetramethylrhodamine (TAMRA) was synthesized in a straightforward procedure utilizing commercially available 5(6)-succinimidyl TAMRA and cystamine hydrochloride. The thiol-containing TAMRA dimer displayed distinct spectral properties in reduced and oxidized forms; covalent dimer formation produced greater effects on the spectral properties than previously reported for noncovalent TAMRA dimers or dimers formed with shorter carbon spacers. The resulting TAMRA disulfide dimer exhibited a hypsochromic shift of 34 nm relative to the reduced monomer species and an isosbestic point at 532 nm between reduced monomeric and oxidized dimeric forms. Molar extinction coefficients of the monomer and dimer relative to moles of TAMRA were similar (6.61 x 10(4) M(-1) cm(-1) and 6.42 x 10(-4) M(-1) cm(-1), respectively). However, fluorescence emission was altered with >93% of dye fluorescence quenched in phosphate buffered saline upon dimer formation. A 520:554 nm absorbance intensity ratio of 2.64 was observed for the oxidized ssTAMRA dimer, almost twice as high as values reported for noncovalent TAMRA dimers. The resulting disulfide dye was easily reduced using both soluble and agarose gel immobilized tris(2-carboxyethyl) phosphine and fresh cell lysate from cultured RAW 264.7 macrophage cells. Absorbance intensity ratios at 554 and 520 nm were used to determine the oxidation half-life of a 1.2 x 10(-5) M solution of reduced TAMRA stored in ambient atmosphere to be approximately 50 h at 22 degrees C. The free thiol dye was further reacted with maleimide-derivatized poly(hydroxypropyl methacrylamide) to yield the dye-labeled polymer conjugate. This dye derivative should prove useful as a dithiol reduction-sensitive fluorescent probe in cellular tracking systems, as well as a thiol-based dye-labeling reagent due to its easy preparation from readily available materials, environmental sensitivity, and simple activation to produce distinct spectral states. The enhanced spectral properties of the covalent TAMRA dimer described here could be useful to prepare more advanced reporter molecules and bioconjugates.

Identification of protein-protein and protein-ribosome interacting regions of the C-terminal tail of human mitochondrial inner membrane protein Oxa1L

The mammalian mitochondrial inner membrane protein Oxa1L is involved in the insertion of a number of mitochondrial translation products into the inner membrane. During this process, the C-terminal tail of Oxa1L (Oxa1L-CTT) binds mitochondrial ribosomes and is believed to coordinate the synthesis and membrane insertion of the nascent chains into the membrane. The C-terminal tail of Oxa1L does not contain any Cys residues. Four variants of this protein with a specifically placed Cys residue at position 4, 39, 67, or 94 of Oxa1L-CTT have been prepared. These Cys residues have been derivatized with a fluorescent probe, tetramethylrhodamine-5-maleimide, for biophysical studies. Oxa1L-CTT forms oligomers cooperatively with a binding constant in the submicromolar range. Fluorescence anisotropy and fluorescence lifetime measurements indicate that contacts near a long helix close to position 39 of Oxa1L-CTT occur during oligomer formation. Fluorescence correlation spectroscopy measurements demonstrate that all of the Oxa1L-CTT derivatives bind to mammalian mitochondrial ribosomes. Steady-state fluorescence quenching and fluorescence lifetime data indicate that there are extensive contacts between Oxa1L-CTT and the ribosome-encompassing regions around positions 39, 67, and 94. The results of this study suggest that Oxa1L-CTT undergoes conformational changes and induced oligomer formation when it binds to the ribosome.

When is weaker better? Design of an ADP sensor with weak ADP affinity, but still selective against ATP

A simple ADP biosensor would be of broad usefulness in monitoring the large number of metabolic processes that produce ADP. Several new systems have been recently described including one in the current issue of ACS Chemical Biology that provides a simple readout of the ADP concentration without significant interference by ATP.

A fluorescent, reagentless biosensor for ADP based on tetramethylrhodamine-labeled ParM

Fluorescence assays for ADP detection are of considerable current interest, both in basic research and in drug discovery, as they provide a generic method for measuring the activity of ATPases and kinases. The development of a novel fluorescent biosensor is described that is based on a tetramethylrhodamine-labeled, bacterial actin homologue, ParM. The design of the biosensor takes advantage of the large conformational change of ParM on ADP binding and the strong quenching of the tetramethylrhodamine fluorescence by stacking of the dye. ParM was labeled with two tetramethylrhodamines in close proximity, whereby the fluorophores are able to interact with each other. ADP binding alters the distance and relative orientation of the tetramethylrhodamines, which leads to a change in this stacking interaction and so in the fluorescence intensity. The final ADP biosensor shows ∼15-fold fluorescence increase in response to ADP binding. It has relatively weak affinity for ADP (K_d = 30 μM), enabling it to be used at substoichiometric concentrations relative to ADP, while reporting ADP concentration changes in a wide range around the K_d value, namely, submicromolar to tens of micromolar. The biosensor strongly discriminates against ATP (>100-fold), allowing ADP detection against a background of millimolar ATP. At 20 °C, the labeled ParM binds ADP with a rate constant of 9.5 × 10⁴ M⁻¹ s⁻¹ and the complex dissociates at 2.9 s⁻¹. Thus, the biosensor is suitable for real-time measurements, and its performance in such assays is demonstrated using a sugar kinase and a mammalian protein kinase.

Early aggregation steps in alpha-synuclein as measured by FCS and FRET: evidence for a contagious conformational change

The kinetics of aggregation of alpha-synuclein are usually studied by turbidity or Thio-T fluorescence. Here we follow the disappearance of monomers and the formation of early oligomers using fluorescence correlation spectroscopy. Alexa488-labeled A140C-synuclein was used as a fluorescent probe in trace amounts in the presence of excess unlabeled alpha-synuclein. Repeated short measurements produce a distribution of diffusion coefficients. Initially, a sharp peak is obtained corresponding to monomers, followed by a distinct transient population and the gradual formation of broader-sized distributions of higher oligomers. The kinetics of aggregation can be followed by the decreasing number of fast-diffusing species. Both the disappearance of fast-diffusing species and the appearance of turbidity can be fitted to the Finke-Watzky equation, but the apparent rate constants obtained are different. This reflects the fact that the disappearance of fast species occurs largely during the lag phase of turbidity development, due to the limited sensitivity of turbidity to the early aggregation process. The nucleation of the early oligomers is concentration-dependent and accompanied by a conformational change that precedes beta-structure formation, and can be visualized using fluorescence resonance energy transfer between the donor-labeled N-terminus and the acceptor-labeled cysteine in the mutant A140C.

Construction of an energy transfer system in the bio-nanocup space by heteromeric assembly of gp27 and gp5 proteins isolated from bacteriophage T4

Protein assemblies, such as viruses and ferritins, have been employed as useful molecular templates for the accumulation of organic and inorganic compounds to construct bio-nanomaterials. While several methods for conjugation of heterofunctional molecules with protein assemblies have been reported, it remains difficult to control their fixation sites in the assemblies. In this article, we demonstrate the three-dimensional arrangement of different types of fluorescent probes using the heteromeric self-assembly of (gp27-gp5)(3) which is the component protein of bacteriophage T4 (gp: gene product). The composites exhibited fluorescence resonance energy transfer from fluorescein to tetramethylrhodamine dyes immobilized in the bio-nanocup space. The alternation of the donor and acceptor positions induced fluorescence self-quenching by the formation of ground-state complexes of the acceptors. These results indicate that the site-specific conjugation method using the bio-nanocup space of the heteromeric protein assembly has potential for the integration of several types of functional molecules in protein nanospaces.

Binding of Dr adhesins of Escherichia coli to carcinoembryonic antigen triggers receptor dissociation

Carcinoembryonic antigen (CEA)-related cell adhesion molecules (CEACAMs) are host receptors for the Dr family of adhesins of Escherichia coli. To define the mechanism for binding of Dr adhesins to CEACAM receptors, we carried out structural studies on the N-terminal domain of CEA and its complex with the Dr adhesin. The crystal structure of CEA reveals a dimer similar to other dimers formed by receptors with IgV-like domains. The structure of the CEA/Dr adhesin complex is proposed based on NMR spectroscopy and mutagenesis data in combination with biochemical characterization. The Dr adhesin/CEA interface overlaps appreciably with the region responsible for CEA dimerization. Binding kinetics, mutational analysis and spectroscopic examination of CEA dimers suggest that Dr adhesins can dissociate CEA dimers prior to the binding of monomeric forms. Our conclusions include a plausible mechanism for how E. coli, and perhaps other bacterial and viral pathogens, exploit CEACAMs. The present structure of the complex provides a powerful tool for the design of novel inhibitory strategies to treat E. coli infections.

Interaction of a self-assembling peptide with oligonucleotides: complexation and aggregation

Molecular interaction of a self-assembling peptide, EAK16-II, to single- and double-stranded oligodeoxynucleotides (ODNs) was investigated under various solution conditions. The molecular events leading to EAK-ODN complexation and further aggregation were elucidated using a series of spectroscopic and microscopic methods. Despite the ability to self-assemble, EAK molecules bind to ODN molecules first upon mixing, resulting in EAK-ODN complexes. The complexes further associate to form EAK-ODN aggregates. A method based on UV-Vis absorption and centrifugation was developed to quantify the fraction of ODNs in the aggregates. The results were used to construct binding isotherms via a binding density function analysis. To compare the effects of different pH values and nucleotide types, the modified noncooperative McGhee and von Hippel model was used to extract binding parameters from the binding isotherms. The binding constant of EAK to ODNs was higher at pH 4 than at pH 7, and no binding was observed at pH 11, indicating that the interaction involved is primarily electrostatic in nature. EAK bound more strongly to single-stranded ODNs. The EAK-ODN aggregates were further visualized using atomic force microscopy; their size distribution as a function of EAK concentration was monitored by dynamic light scattering. The timescale for the EAK-ODN aggregation was on the order of minutes by fluorescence anisotropy and steady-state light scattering experiments. Fluorescence quenching experiments demonstrated that the ODNs in the aggregates were less accessible to the solvent, demonstrating a potential of oligonucleotide encapsulation by the self-assembling peptide.

A biosensor for inorganic phosphate using a rhodamine-labeled phosphate binding protein

A novel biosensor for inorganic phosphate (Pi) has been developed based on the phosphate binding protein of Escherichia coli. Two cysteine mutations were introduced and labeled with 6-iodoacetamidotetramethylrhodamine. When physically close to each other and correctly oriented, two rhodamine dyes interact to form a noncovalent dimer. In this state, they have little or no fluorescence, unlike the high fluorescence intensity of monomeric rhodamine. The labeling sites were so placed that the distance and orientation between the rhodamines change as a consequence of the conformational change associated with Pi binding. This movement alters the extent of interaction between the dyes. The best mutant of those tested (A17C, A197C) gives rise on average to approximately 18-fold increase in fluorescence intensity as Pi binds. The kinetics of interaction with Pi were measured at 10 degrees C. Under these conditions, the fluorescence increase associated with Pi binding has a maximum rate of 267 s-1. The Pi dissociation rate is 6.6 s-1, and the dissociation constant is 70 nM. An application of the sensor is demonstrated for measuring ATP hydrolysis in real time as a helicase moves along DNA. Advantages of the new sensor are discussed, both in terms of the use of a rhodamine fluorophore and the potential of this double labeling strategy.

Development of fluorescent biosensors for probing the function of motor proteins

Biosensors are becoming widely used both in basic research and in screening assays and reagentless sensors with fluorescent reporter groups attached to proteins form one class. This article describes the development of sensors for two small molecules, driven in particular by the need for high sensitivity and time resolution to probe mechanistic aspects of ATP-coupled motor proteins. The biosensors are for the products of the ATPase reaction, ADP and inorganic phosphate. The interplay between the possibilities for design and understanding the mechanism of the signal are discussed. Examples are described of how these sensors have been applied to understanding myosin and helicase motors.

Oligomeric state and mode of self-association of Thermotoga maritima ribosomal stalk protein L12 in solution

The "stalk" of the prokaryotic 50S ribosomal subunit is comprised of four copies of the protein L7/L12. In Escherichia coli, L7/L12 is a dimeric protein at micromolar concentrations, which is able to undergo rapid subunit exchange. A recent structural study indicated a tetrameric arrangement of the L12 proteins isolated from Thermotoga maritima, in which the proteins engaged in two different dimerization modes. In one mode, the two monomers of L12 form a tight symmetric and parallel dimer held together by a four-helix bundle, which encompasses the hinge region between the N- and C-terminal domains. In the other mode, the two monomers bind through their N-terminal region in an antiparallel configuration, in which one monomer comprises an alpha-helical hinge and the other monomer adopts an elongated shape with an unfolded hinge region. Presently, it is unclear which dimer contact prevails in solution and on the ribosome. Using cysteine mutants of T. maritima labeled with fluorescent probes, we investigated the mode of interactions between L12 subunits. Data from Forster resonance energy transfer experiments support a dimerization of L12 in solution, in which two monomers bind through their N-terminal region in an antiparallel configuration. We also demonstrate that the rate of subunit exchange in T. maritima L12 is significantly slower at 25 degrees C than that in the E. coli system. The exchange rate increases with increasing temperature and approaches the one observed for the E. coli system at 50 degrees C. Possible factors responsible for this difference are discussed.

Distances between Tropomyosin Sites Across the Muscle Thin Filament Using Luminescence Resonance Energy Transfer: Evidence for Tropomyosin Flexibility

To obtain information about the interaction of tropomyosin (Tm) with actin associated with the regulatory states of the muscle thin filament, we used luminescence resonance energy transfer (LRET) between Tb(3+) as a donor and rhodamine as an acceptor. A novel Tb(3+) chelator, S-(2-nitro-5-thiobenzoate)cysteaminyl-DTPA-Cs124, was synthesized, which specifically labels Cys groups in proteins. With the Tb chelate as the donor and tetramethylrhodamine-5-maleimide as the acceptor, both bound to specific Cys groups of Tm, we obtained 67 A as the distance between Tm's across the actin filament, a much shorter value than that obtained from structural studies (72-86 A). The difference appears to be due to submillisecond motion associated with Tm flexibility, which brings the probes closer during the millisecond lifetime of the donor. Ca(2+) did not change the energy transfer with the reconstituted thin filament, but myosin subfragment 1 decreased the transfer, consistent with either a 5-6 A increase in distance or, more likely, a decrease in flexibility.

A point mutation in ribosomal protein L7/L12 reduces its ability to form a compact dimer structure and to assemble into the GTPase center

An Escherichia coli mutant, LL103, harboring a mutation (Ser15 to Phe) in ribosomal protein L7/L12 was isolated among revertants of a streptomycin-dependent strain. In the crystal structure of the L7/L12 dimer, residue 15 within the N-terminal domain contacts the C-terminal domain of the partner monomer. We tested effects of the mutation on molecular assembly by biochemical approaches. Gel electrophoretic analysis showed that the Phe15-L7/L12 variant had reduced ability in binding to L10, an effect enhanced in the presence of 0.05% of nonionic detergent. Mobility of Phe15-L7/L12 on gel containing the detergent was very low compared to the wild-type proteins, presumably because of an extended structural state of the mutant L7/L12. Ribosomes isolated from LL103 cells contained a reduced amount of L7/L12 and showed low levels (15-30% of wild-type ribosomes) of activities dependent on elongation factors and in translation of natural mRNA. The ribosomal activity was completely recovered by addition of an excess amount of Phe15-L7/L12 to the ribosomes, suggesting that the mutant L7/L12 exerts normal functions when bound on the ribosome. The interaction of Ser15 with the C-terminal domain of the partner molecule seems to contribute to formation of the compact dimer structure and its efficient assembly into the ribosomal GTPase center. We propose a model relating compact and elongated forms of L7/L12 dimers. Phe15-L7/L12 provides a new tool for studying the functional structure of the homodimer.

Structural and biochemical characterization of a fluorogenic rhodamine-labeled malarial protease substrate

Activation of the proenzyme form of the malarial protease PfSUB-1 involves the autocatalytic cleavage of an Asp-Asn bond within the internal sequence motif (215)LVSADNIDIS(224). A synthetic decapeptide based on this sequence but with the N- and C-terminal residues replaced by cysteines (Ac-CVSADNIDIC-OH) was labeled with 5- or 6-isomers of iodoacetamidotetramethylrhodamine (IATR). The doubly labeled peptides have low fluorescence because of ground-state, noncovalent dimerization of the rhodamines. Cleavage of either peptide by recombinant PfSUB-1 results in dissociation of the rhodamine dimers, which abolishes the self-quenching and consequently leads to an approximately 30-fold increase in the fluorescence. This spectroscopic signal provides a continuous assay of proteolysis, enabling quantitative kinetic measurements to be made, and has also enabled the development of a fluorescence-based assay suitable for use in high-throughput screens for inhibitors of PfSUB-1. The structure of the rhodamine dimer in the 6-IATR-labeled peptide was shown by NMR to be a face-to-face stacking of the xanthene rings. Time-resolved fluorescence measurements suggest that the doubly labeled peptides exist in an equilibrium consisting of rhodamines involved in dimers (closed forms) and rhodamines not involved in dimers (open forms). These data also indicate that the rhodamine dimers fluoresce and that the associated lifetimes are subnanosecond.

Measuring kinesin's first step

A variety of models have recently emerged to explain how the molecular motor kinesin is able to maintain processive movement for over 100 steps. Although these models differ in significant features, they all predict that kinesin's catalytic domains intermittently separate from each other as the motor takes 8-nm steps along the microtubule. Furthermore, at some point in this process, one molecule of ATP is hydrolyzed per step. However, exactly when hydrolysis and product release occur in relation to this forward step have not been established. Furthermore, the rate at which this separation occurs as well as the speed of motor stepping onto and release from the microtubule have not been measured. In the absence of this information, it is difficult to critically evaluate competing models of kinesin function. We have addressed this issue by developing spectroscopic probes whose fluorescence is sensitive to motor-motor separation or microtubule binding. The kinetics of these fluorescence changes allow us to directly measure how fast kinesin steps onto and releases from the microtubule and provide insight into how processive movement is maintained by this motor.

Global configuration of single titin molecules observed through chain-associated rhodamine dimers

The global configuration of individual, surface-adsorbed molecules of the giant muscle protein titin, labeled with rhodamine conjugates, was followed with confocal microscopy. Fluorescence-emission intensity was reduced because of self-quenching caused by the close spacing between rhodamine dye molecules that formed dimers. In the presence of chemical denaturants, fluorescence intensity increased, reversibly, up to 5-fold in a fast reaction; the kinetics were followed at the single-molecule level. We show that dimers formed in a concentrated rhodamine solution dissociate when exposed to chemical denaturants. Furthermore, titin denaturation, followed by means of tryptophan fluorescence, is dominated by a slow reaction. Therefore, the rapid fluorescence change of the single molecules reflects the direct action of the denaturants on rhodamine dimers rather than the unfolding/refolding of the protein. Upon acidic denaturation, which we have shown not to dissociate rhodamine dimers, fluorescence intensity change was minimal, suggesting that dimers persist because the unfolded molecule has contracted into a small volume. The highly contractile nature of the acid-unfolded protein molecule derives from a significant increase in chain flexibility. We discuss the potential implications this finding could have for the passive mechanical behavior of striated muscle.

Pivotal role of the P1 N-terminal domain in the assembly of the mammalian ribosomal stalk and in the proteosynthetic activity

In the 60 S ribosomal subunit, the lateral stalk made of the P-proteins plays a major role in translation. It contains P0, an insoluble protein anchoring P1 and P2 to the ribosome. Here, rat recombinant P0 was overproduced in inclusion bodies and solubilized in complex with the other P-proteins. This method of solubilization appeared suitable to show protein complexes and revealed that P1, but not P2, interacted with P0. Furthermore, the use of truncated mutants of P1 and P2 indicated that residues 1-63 in P1 connected P0 to residues 1-65 in P2. Additional experiments resulted in the conclusion that P1 and P2 bound one another, either connected with P0 or free, as found in the cytoplasm. Accordingly, a model of association for the P-proteins in the stalk is proposed. Recombinant P0 in complex with phosphorylated P2 and either P1 or its (1-63) domain efficiently restored the proteosynthetic activity of 60 S subunits deprived of native P-proteins. Therefore, refolded P0 was functional and residues 1-63 only in P1 were essential. Furthermore, our results emphasize that the refolding principle used here is worth considering for solubilizing other insoluble proteins.

Arrangement of apolipoprotein A-I in reconstituted high-density lipoprotein disks: an alternative model based on fluorescence resonance energy transfer experiments

The folding and organization of apolipoprotein A-I (apoA-I) in discoidal, high-density lipoprotein (HDL) complexes with phospholipids are not yet completely resolved. For about 20 years, it was generally accepted that the amphipathic helices of apoA-I lie parallel to the acyl chains of the phospholipids ("picket fence" model). However, based on the X-ray crystal structure of a large, lipid-free fragment of apoA-I, a "belt model" was recently proposed. In this model, the helices of two antiparallel apoA-I molecules are extended in a circular arrangement and lie perpendicular to the phospholipid acyl chains. To obtain conclusive information on the spatial organization of apoA-I in discoidal HDL, we engineered three separate cysteine mutants of apoA-I (D9C, A124C, A232C) for specific labeling with the fluorescence probes ALEXA-488 or ALEXA-546 (fluorescein and rhodamine derivatives). The labeled apoA-I was reconstituted into well-defined HDL complexes containing two molecules of protein and dipalmitoylphosphatidylcholine, and the complexes were used in three quantitative fluorescence resonance energy transfer (FRET) experiments to determine the distances between two specific sites in an HDL particle. Comparison of the distances measured by FRET (4.7-7.8 nm) with those predicted from the existing models indicated that neither the picket fence nor the belt model can account for the experimental results; rather, a hairpin folding of each apoA-I monomer with most helices perpendicular to the phospholipid acyl chains and a random head-to-tail and head-to-head arrangement of the two apoA-I molecules in the HDL particles are strongly suggested by the distance and lifetime data.

Structural investigations of the highly flexible recombinant ribosomal protein L12 from Thermotoga maritima

Ribosomal protein L7/L12, the only multicopy component of the ribosome, is involved in translation factor binding and in the ribosomal GTPase center. The gene for L7/L12 from Thermotoga maritima was cloned and the protein expressed at high levels in Escherichia coli. Purification of L7/L12 was achieved under non-denaturing conditions via heat treatment and two chromatographic steps. Circular dichroism melting profiles were monitored at 222 nm, showing the melting temperature of the protein at pH 7.5 around 110 degrees C, compared to approximately 60 degrees C for the highly homologous Escherichia coli protein. The unfolding was reversible and renaturation closely followed the path of the thermal melting. Dynamic light scattering, gel filtration chromatography, and crosslinking experiments suggested that under physiological buffer conditions Thermotoga maritima L7/L12 exists as a tetramer. The protein was crystallized under two conditions, yielding an orthorhombic (C222(1)) and a cubic (12(1)3) space group with an estimated two and three to four L7/L12 molecules per asymmetric unit, respectively. The crystals contained the full-length protein, and cryogenic buffers were developed which improved the mosaic spreads and the resolution limits. For the structure solution isoleucine was mutated to methionine at two separate positions, the mutant forms expressed as selenomethionine variants and crystallized.

Flexibility, conformational diversity and two dimerization modes in complexes of ribosomal protein L12

Protein L12, the only multicopy component of the ribosome, is presumed to be involved in the binding of translation factors, stimulating factor-dependent GTP hydrolysis. Crystal structures of L12 from Thermotogamaritima have been solved in two space groups by the multiple anomalous dispersion method and refined at 2.4 and 2.0 A resolution. In both crystal forms, an asymmetric unit comprises two full-length L12 molecules and two N-terminal L12 fragments that are associated in a specific, hetero-tetrameric complex with one non-crystallographic 2-fold axis. The two full-length proteins form a tight, symmetric, parallel dimer, mainly through their N-terminal domains. Each monomer of this central dimer additionally associates in a different way with an N-terminal L12 fragment. Both dimerization modes are unlike models proposed previously and suggest that similar complexes may occur in vivo and in situ. The structures also display different L12 monomer conformations, in accord with the suggested dynamic role of the protein in the ribosomal translocation process. The structures have been submitted to the Protein Databank (http://www.rcsb.org/pdb) under accession numbers 1DD3 and 1DD4.

Photophysical analysis of class I major histocompatibility complex protein assembly using a xanthene-derivatized beta2-microglobulin

Spectral changes and a sixfold increase in the emission intensity were observed in the fluorescence of a single xanthene probe (Texas red) attached to beta2m-microglobulin (beta2m) upon assembly of beta2m into a ternary complex with mouse H-2Kd heavy chain and influenza nuclear protein peptide. Dissociation of the labeled beta2m from the ternary complex restored the probe's fluorescence and absorption spectra and reduced the emission intensity. Thus changes in xanthene probe fluorescence upon association/dissociation of the labeled beta2m molecule with/from the ternary complex provide a simple and convenient method for studying the assembly/dissociation mechanism of the class I major histocompatibility complex (MHC-I) encoded molecule. The photophysical changes in the probe can be accounted for by the oligomerization of free labeled beta2m molecules. The fluorescence at 610 nm is due to beta2m dimers, where the probes are significantly separated spatially so that their emission and excitation properties are close to those of xanthene monomers. Fluorescence around 630 nm is due to beta2m oligomers where xanthene probes interact. Minima in the steady-state excitation (550 nm) and emission (630 nm) anisotropy spectra correlate with the maxima of the high-order oligomer excitation and emission spectra, showing that their fluorescence is more depolarized. These photophysical features are explained by splitting of the first singlet excited state of interacting xanthene probes that can be modeled by exciton theory.

A single-headed dimer of Escherichia coli ribosomal protein L7/L12 supports protein synthesis

During protein synthesis, the two elongation factors Tu and G alternately bind to the 50S ribosomal subunit at a site of which the protein L7/L12 is an essential component. L7/L12 is present in each 50S subunit in four copies organized as two dimers. Each dimer consists of distinct domains: a single N-terminal ("tail") domain that is responsible for both dimerization and binding to the ribosome via interaction with the protein L10 and two independent globular C-terminal domains ("heads") that are required for binding of elongation factors to ribosomes. The two heads are connected by flexible hinge sequences to the N-terminal domain. Important questions concerning the mechanism by which L7/L12 interacts with elongation factors are posed by us in response to the presence of two dimers, two heads per dimer, and their dynamic, mobile properties. In an attempt to answer these questions, we constructed a single-headed dimer of L7/L12 by using recombinant DNA techniques and chemical cross-linking. This chimeric molecule was added to inactive core particles lacking wild-type L7/L12 and shown to restore activity to a level approaching that of wild-type two-headed L7/L12.

Evolutionary analyses of the 12-kDa acidic ribosomal P-proteins reveal a distinct protein of higher plant ribosomes

The P-protein complex of eukaryotic ribosomes forms a lateral stalk structure in the active site of the large ribosomal subunit and is thought to assist in the elongation phase of translation by stimulating GTPase activity of elongation factor-2 and removal of deacylated tRNA. The complex in animals, fungi, and protozoans is composed of the acidic phosphoproteins P0 (35 kDa), P1 (11-12 kDa), and P2 (11-12 kDa). Previously we demonstrated by protein purification and microsequencing that ribosomes of maize (Zea mays L.) contain P0, one type of P1, two types of P2, and a distinct P1/P2 type protein designated P3. Here we implemented distance matrices, maximum parsimony, and neighbor-joining analyses to assess the evolutionary relationships between the 12 kDa P-proteins of maize and representative eukaryotic species. The analyses identify P3, found to date only in mono- and dicotyledonous plants, as an evolutionarily distinct P-protein. Plants possess three distinct groups of 12 kDa P-proteins (P1, P2, and P3), whereas animals, fungi, and protozoans possess only two distinct groups (P1 and P2). These findings demonstrate that the P-protein complex has evolved into a highly divergent complex with respect to protein composition despite its critical position within the active site of the ribosome.

Cross-linking of selected residues in the N- and C-terminal domains of Escherichia coli protein L7/L12 to other ribosomal proteins and the effect of elongation factor Tu

Five different variants of protein L7/L12, each with a single cysteine substitution at a selected site, were produced, modified with 125I-N-[4-(p-azidosalicylamido)-butyl]-3-(2'-pyridyldithio)propion amide, a radiolabeled, sulfhydryl-specific, heterobifunctional, cleavable photocross-linking reagent that transfers radiolabel to the target molecule upon reduction of the disulfide bond. The proteins were reconstituted with core particles depleted of wild type L7/L12 to yield 70 S ribosomes. Cross-linked molecules were identified and quantified by the radiolabel. No cross-linking of RNA was detected. Two sites in the dimeric N-terminal domain, Cys-12 and Cys-33, cross-linked strongly to L10 and in lower yield to L11 but to no other proteins. The three sites in the globular C-terminal domain all cross-linked strongly to L11 and, in lower yield, to L10. Weaker cross-linking to 50 S proteins L2 and L5 occurred from all three C-terminal domain locations. The 30 S ribosomal proteins S2, S3, S7, S14, S18 were also cross-linked from all three of these sites. Binding of the ternary complex [14C]Phe-tRNA-elongation factor Tu.guanyl-5'-yl imidodiphosphate) but not [14C]Phe-tRNA.elongation factor Tu.GDP.kirromycin increased labeling of L2, L5, and all of the 30 S proteins. These results imply the flexibility of L7/L12 and the transient proximity of three surfaces of the C-terminal domain with the base of the stalk, the peptidyl transferase domain, and the head of the 30 S subunit.

Characterization of fluorescence quenching in bifluorophoric protease substrates

NorFES is a relatively rigid, bent undecapeptide which contains an amino acid sequence that is recognized by the serine protease elastase (AspAlaIleProNle downward arrow SerIleProLysGlyTyr ( downward arrow indicates the primary cleavage site)). Covalent attachment of a fluorophore on each side of NorFES's elastase cleavage site enables one to use a change of fluorescence intensity as a measure of enzymatic activity. In this study two bichromophoric NorFES derivatives, D-NorFES-A and D-NorFES-D, were prepared in which D (donor) was tetramethylrhodamine and A (acceptor) was rhodamine-X, two chromophores with characteristics suitable for energy transfer. Absorption and fluorescence spectra were obtained with both the intact and cleaved homodoubly, heterodoubly and singly labeled derivatives. It was found that both the homo and hetero doubly-labeled derivatives form ground-state complexes which exhibit exciton bands. The hetero labeled derivative exhibits little or no resonance energy transfer. Spectral measurements were also done in urea, which partially disrupts ground-state dimers.

Localization of two domains of a mutant form of Escherichia coli protein L7/L12 that binds the large ribosomal subunit as a single dimer

Escherichia coli ribosomal protein L7/L12 occurs on the large subunit as two dimers: one dimer is extended and comprises the stalk, while the second dimer is folded and occupies a site on the subunit body. A variant protein, in which all 18 amino acids of the flexible hinge region that links separate N-terminal and C-terminal domains of L7/L12 has been deleted, binds the subunit as a single dimer and does not generate stalks that are visible in electron micrographs. Monoclonal antibodies directed against each domain of the protein have been used to localize the variant in electron micrographs of 50S subunits. Both C-terminal domains are seen at a shoulder of the subunit, near its edge as viewed in the most common quasisymmetric projection. N-terminal domains are placed on the subunit body, about 50 A from the C-terminal domains. The antibody to the N-terminal domain also causes dissociation of the variant dimer from the particle and the formation of oligomeric antibody-protein dimer complexes. Similar complexes were seen previously (Olson HM et al (1986) J Biol Chem 261, 6924-6936) when this antibody induced dissociation of one dimer of the native protein. We conclude that the shortened variant most probably occupies the lower-affinity site on the subunit that is normally filled by the stalk dimer.

Rotational and conformational dynamics of Escherichia coli ribosomal protein L7/L12

Fluorescence methods were utilized to study dynamic aspects of the 24 kDa dimeric Escherichia coli ribosomal protein L7/L12. Oligonucleotide site-directed mutagenesis was used to introduce cysteine residues at specific locations along the peptide chain, in both the C-terminal and N-terminal domains, and various sulfhydryl reactive fluorescence probes (iodoacetamido) fluorescein, IAEDANS, pyrenemethyl iodoacetate) were attached to these residues. In addition to the full-length proteins, a hinge-deleted variant and variants corresponding to the C-terminal fragment and the N-terminal fragment were also studied. Both steady-state and time-resolved fluorescence measurements were carried out, and the results demonstrated that L7/L12 is not a rigid molecule. Specifically, the two C-terminal domains move freely with respect to one another and with respect to the dimeric N-terminal domain. Removal of the hinge region, however, significantly reduces the mobility of the C-terminal domains. The data also show that the rotational relaxation time monitored by the fluorescent probe-depends upon the probe's excited state lifetime. This observation is interpreted to indicate that a hierarchy of motions exists in the L7/L12 molecule including facile motions of the C-terminal domains and dimeric N-terminal domain, in addition to the overall tumbling of the protein. Probes attached to the N-terminal domain exhibit global rotational relaxation times consistent with the molecular mass of the dimeric N-terminal fragment. Upon reconstitution of labeled L7/L12 with ribosomal cores, however, the motion associated with the dimeric N-terminal domain is greatly diminished while the facile motion of the C-terminal domains is almost unchanged.

Dimer/monomer equilibrium and domain separations of Escherichia coli ribosomal protein L7/L12

The dimer to monomer equilibrium and interdomain separations of cysteine variants of L7/L12 have been investigated using fluorescence spectroscopy. Steady-state polarization measurements on cysteine containing variants of L7/L12, labeled with 5-(iodoacetamido)fluorescein, demonstrated dimer to monomer dissociation constants near 30 nM for variants labeled at position 33, in the N-terminal domain, and positions 63 and 89, in the C-terminal domain. A dissociation constant near 300 nM was determined for a variant labeled at position 12, in the N-terminal domain. The polarization of a labeled C-terminal fragment did not change over the range of 200 microM to 1 nM, indicating that this construct remains monomeric at these concentrations, whereas a dimer to monomer dissociation constant near 300 nM was observed for an FITC labeled N-terminal fragment. Intersubunit fluorescence resonance energy self-transfer was observed when appropriate probes were attached to cysteines at residues 12 or 33, located in the N-terminal domain. Probes attached to cysteines at positions 63 or 89 in the C-terminal domain, however, did not exhibit intersubunit self-transfer. These results indicate that these residues in the C-terminal domains are, on average, separated by greater than 85 A. Intersubunit self-transfer does occur in a C-89 double mutation variant lacking 11 residues in the putative hinge region, indicating that the loss of the hinge region brings the two C-terminal domains closer together. Rapid subunit exchange between unlabeled wild-type L7/L12 and L7/L12 variants labeled in the N-terminal domain was also demonstrated by the loss of self-transfer upon mixing of the two proteins.