Application of fluorescence resonance energy transfer to the GroEL-GroES chaperonin reaction.

Fluorescence resonance energy transfer (FRET) is a sensitive and flexible method for studying protein-protein interactions. Here it is applied to the GroEL-GroES chaperonin system to examine the ATP-driven dynamics that underlie protein folding by this chaperone. Relying on the known structures of GroEL and GroES, sites for attachment of fluorescent probes are designed into the sequence of both proteins. Because these sites are brought close in space when GroEL and GroES form a complex, excitation energy can pass from a donor to an acceptor chromophore by FRET. While in ideal circumstances FRET can be used to measure distances, significant population heterogeneity in the donor-to-acceptor distances in the GroEL-GroES complex makes distance determination difficult. This is due to incomplete labeling of these large, oligomeric proteins and to their rotational symmetry. It is shown, however, that FRET can still be used to follow protein-protein interaction dynamics even in a case such as this, where distance measurements are either not practical or not meaningful. In this way, the FRET signal is used as a simple proximity sensor to score the interaction between GroEL and GroES. Similarly, FRET can also be used to follow interactions between GroEL and a fluorescently labeled substrate polypeptide. Thus, while knowledge of molecular structure aids enormously in the design of FRET experiments, structural information is not necessarily required if the aim is to measure the thermodynamics or kinetics of a protein interaction event by following changes in the binding proximity of two components.

GroEL-GroES cycling: ATP and nonnative polypeptide direct alternation of folding-active rings.

The double-ring chaperonin GroEL mediates protein folding in the central cavity of a ring bound by ATP and GroES, but it is unclear how GroEL cycles from one folding-active complex to the next. We observe that hydrolysis of ATP within the cis ring must occur before either nonnative polypeptide or GroES can bind to the trans ring, and this is associated with reorientation of the trans ring apical domains. Subsequently, formation of a new cis-ternary complex proceeds on the open trans ring with polypeptide binding first, which stimulates the ATP-dependent dissociation of the cis complex (by 20- to 50-fold), followed by GroES binding. These results indicate that, in the presence of nonnative protein, GroEL alternates its rings as folding-active cis complexes, expending only one round of seven ATPs per folding cycle.

Structure and function in GroEL-mediated protein folding.

Recent structural and biochemical investigations have come together to allow a better understanding of the mechanism of chaperonin (GroEL, Hsp60)-mediated protein folding, the final step in the accurate expression of genetic information. Major, asymmetric conformational changes in the GroEL double toroid accompany binding of ATP and the cochaperonin GroES. When a nonnative polypeptide, bound to one of the GroEL rings, is encapsulated by GroES to form a cis ternary complex, these changes drive the polypeptide into the sequestered cavity and initiate its folding. ATP hydrolysis in the cis ring primes release of the products, and ATP binding in the trans ring then disrupts the cis complex. This process allows the polypeptide to achieve its final native state, if folding was completed, or to recycle to another chaperonin molecule, if the folding process did not result in a form committed to the native state.

Distinct actions of cis and trans ATP within the double ring of the chaperonin GroEL.

The chaperonin GroEL is a double-ring structure with a central cavity in each ring that provides an environment for the efficient folding of proteins when capped by the co-chaperone GroES in the presence of adenine nucleotides. Productive folding of the substrate rhodanese has been observed in cis ternary complexes, where GroES and polypeptide are bound to the same ring, formed with either ATP, ADP or non-hydrolysable ATP analogues, suggesting that the specific requirement for ATP is confined to an action in the trans ring that evicts GroES and polypeptide from the cis side. We show here, however, that for the folding of malate dehydrogenase and Rubisco there is also an absolute requirement for ATP in the cis ring, as ADP and AMP-PNP are unable to promote folding. We investigated the specific roles of binding and hydrolysis of ATP in the cis and trans rings using mutant forms of GroEL that bind ATP but are defective in its hydrolysis. Binding of ATP and GroES in cis initiated productive folding inside a highly stable GroEL-ATP-GroES complex. To discharge GroES and polypeptide, ATP hydrolysis in the cis ring was required to form a GroEL-ADP-GroES complex with decreased stability, priming the cis complex for release by ATP binding (without hydrolysis) in the trans ring. These observations offer an explanation of why GroEL functions as a double-ring complex.

Environment-sensitive labels in multiplex fluorescence analyses of protein-DNA complexes.

Fluorescein is widely used for protein labeling because of its high extinction coefficient and fluorescence emission quantum yield. However, its emission is readily quenched by various pathways. We exploit these properties of fluorescein to examine the self-association of a DNA binding protein and determine the amount of the protein in gel-shifted complexes with specific DNA. A construct (HSFDT385SH) of the heat shock transcription factor (HSF) was expressed that contains the DNA-binding and trimerization domains, residues 192-385 of HSF, with four additional COOH-terminal residues, GMLC, and then labeled at the COOH-terminal cysteine with fluorescein 5-maleimide to form HSFDT385-Fl. The fluorescence increase accompanying the formation of heterotrimers on titration of HSFDT385-Fl with HSFDT385SH) led to an estimate of 3 x 10(-16) M2 for the equilibrium constant for trimerization of HSFDT385SH. HSFDT385-Fl fluorescence also increased 1.7-fold on binding to specific DNA, but not to nonspecific DNA. The protein and DNA content of the several gel-shifted complexes of HSFDT385-Fl (lambdamaxem 532 nm) with specific DNA labeled noncovalently with the energy transfer heterodimer TOTAB (lambdamaxem 658 nm) were accurately determined by a two-color fluorescence emission assay with 488 nm excitation.

Characterization of the active intermediate of a GroEL-GroES-mediated protein folding reaction.

Recent studies of GroE-mediated protein folding indicate that substrate proteins are productively released from a cis ternary complex in which the nonnative substrate is sequestered within the GroEL channel underneath GroES. Here, we examine whether protein folding can occur in this space. Stopped-flow fluorescence anisotropy of a pyrene-rhodanese-GroEl complex indicates that addition of GroES and ATP (but not ADP) leads to a rapid change in substrate flexibility at GroEL. Strikingly, when GroES release is blocked by the use of either a nonhydrolyzable ATP analog or a single-ring GroEL mutant, substrates complete folding while remaining associated with chaperonin. We conclude that the cis ternary complex, in the presence of ATP, is the active state intermediate in the GroE-mediated folding reaction: folding is initiated in this state and for some substrates may be completed prior to the timed release of GroES triggered by ATP hydrolysis.

Interaction of dimeric intercalating dyes with single-stranded DNA.

The unsymmetrical cyanine dye thiazole orange homodimer (TOTO) binds to single-stranded DNA (ssDNA, M13mp18 ssDNA) to form a fluorescent complex that is stable under the standard conditions of electrophoresis. The stability of this complex is indistinguishable from that of the corresponding complex of TOTO with double-stranded DNA (dsDNA). To examine if TOTO exhibits any binding preference for dsDNA or ssDNA, transfer of TOTO from pre-labeled complexes to excess unlabeled DNA was assayed by gel electrophoresis. Transfer of TOTO from M13 ssDNA to unlabeled dsDNA proceeds to the same extent as that from M13 dsDNA to unlabeled dsDNA. A substantial amount of the dye is retained by both the M13 ssDNA and M13 dsDNA even when the competing dsDNA is present at a 600-fold weight excess; for both dsDNA and ssDNA, the pre-labeled complex retains approximately one TOTO per 30 bp (dsDNA) or bases (ssDNA). Rapid transfer of dye from both dsDNA and ssDNA complexes is seen at Na+ concentrations > 50 mM. Interestingly, at higher Na+ or Mg2+ concentrations, the M13 ssDNA-TOTO complex appears to be more stable to intrinsic dissociation (dissociation in the absence of competing DNA) than the complex between TOTO and M13 dsDNA. Similar results were obtained with the structurally unrelated dye ethidium homodimer. The dsDNA- and ssDNA-TOTO complexes were further examined by absorption, fluorescence and circular dichroism spectroscopy. The surprising conclusion is that polycationic dyes, such as TOTO and EthD, capable of bis-intercalation, interact with dsDNA and ssDNA with very similar high affinity.

High-sensitivity capillary electrophoresis of double-stranded DNA fragments using monomeric and dimeric fluorescent intercalating dyes.

Fluorescence-detected capillary electrophoresis separations of phi X174/HaeIII DNA restriction fragments have been performed using monomeric and dimeric intercalating dyes. Replaceable hydroxyethyl cellulose solutions were used as the separation medium. Confocal fluorescence detection was performed following 488-nm laser excitation. The limits of DNA detection for on-column staining with monomeric dyes (ethidium bromide, two propidium dye derivatives, oxazole yellow, thiazole orange, and a polycationic thiazole orange derivative) were determined. The thiazole orange dyes provide the most sensitive detection with limiting sensitivities of 2-4 amol of DNA base pairs per band, and detection of the 603-bp fragment was successful, injecting from phi X174/HaeIII samples containing only 1-2 fg of this fragment per microliter. Separations of preformed DNA-dimeric dye complexes were also performed. The breadth of the bands observed in separations of preformed DNA-dimeric dye complexes is due to the presence of DNA fragments with different numbers of bound dye molecules that can be resolved as closely spaced subbands in many of our separations. The quality of these DNA-dye complex separations can be dramatically improved by performing the electrophoresis with 9-aminoacridine (9AA) in the column and running buffers. The optimum concentrations of 9AA for the separation of complexes preformed with the dimeric dyes TOTO, EthD, TOTAB, and YOYO were determined to be 100, 1, 1, and 0.5 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Stable fluorescent dye-DNA complexes in high sensitivity detection of protein-DNA interactions. Application to heat shock transcription factor.

The gel mobility-shift assay is an important tool for the study of protein-nucleic acid interactions. High detection sensitivity is typically attained by radioisotopic labeling of the target nucleic acid fragments. A novel fluorescence methodology offers significant advantages over this conventional approach. Ethidium, thiazole orange, and oxazole yellow homodimers form stable, highly fluorescent complexes with double-stranded DNA that can be detected in gels by a laser-excited, confocal, fluorescence scanning system with a sensitivity higher than that attainable with radioisotopic labeling. We describe here the use of these dyes in a gel-mobility assay to detect complexes of a truncation of the Kluyveromyces lactis heat shock transcription factor, containing the trimerization and DNA-binding domains (HSFDT), with target DNA. At an appropriate molar DNA base pair to dye ratio, the labeling of a DNA fragment with dimeric dye did not affect the binding to HSFDT. The detection of the fluorescent-dye labeled HSFDT-DNA complexes with the laser scanner achieves a spatial resolution far superior to that of conventional autoradiography and permits analysis of multimer protein-DNA complexes that are not resolved by traditional detection methods. We have used this technique to demonstrate that HSF forms multimeric complexes on DNA by addition of trimeric units. The latter conclusion is based on an analysis of the mobilities of the multiple HSFDT-DNA complexes and on a two-color mobility-shift fluorescence assay that uses a mutant of HSFDT engineered for site-specific labeling with fluorescein and target DNA labeled with an "energy transfer" dye, thiazole orange-thiazole blue heterodimer.

Picogram detection of stable dye-DNA intercalation complexes with two-color laser-excited confocal fluorescence gel scanner.

The stable complexes between highly fluorescent, polyfunctional intercalators and dsDNA can be used to detect dsDNA in agarose gels at picogram levels and for multicolor detection of multiplexed dsDNA fragments. Development of additional DNA-binding fluorophores with appropriate spectroscopic properties will expand the range of applications. In principle, the DNA-dye intercalation complexes represent a more sensitive alternative to an established approach to fluorescent labeling and detection of restriction fragments by ligation to single-stranded short oligonucleotides labeled with different fluorochromes, followed by separation on denaturing polyacrylamide gels. The latter technique gives near single-base resolution up to 400 bases and the ability to quantitate fragment size up to 2000 bases, and has been successfully applied to cosmid mapping. Detection of DNA fragments as intercalation complexes requires that the separations be performed on agarose gels under nondenaturing conditions. Such conditions have been used for extensive mapping of yeast cosmids with postelectrophoresis staining with ethidium bromide. For the patterns on agarose gels, the magnitude of the "error window," which specifies how similar two fragments must be before the corresponding fragments in different digests are paired, was reported to be strongly size dependent. The error window was expanded by a factor of 1.3 for fragments from 400 to 600 bp, 1.2 for fragments from 600 to 800 bp, and 1.1 for fragments from 800 to 1000 bp. Moreover, it was necessary to introduce corrections for systematic differences between size estimates taken from two different gels. For the multiplexing procedure described here, the size estimates for fragments from 600 bp to over 23 kbp were in close agreement with actual sizes as determined from DNA sequence (Table I), and certainly within the error windows given above. The multiplexing procedure should also minimize errors introduced by gel-to-gel variations in mobility, because the standard and unknowns are always run in the same lanes. Kohara et al. established a physical map of almost the entire Escherichia coli chromosome by analysis of a large genomic library. In this case, partial restriction digests were used to generate patterns of fragments and the mapping was performed by agarose gel electrophoresis. The disadvantage of this approach is that fewer fragments are generated. However, this is compensated for by the fact that partial digests reveal the order of the fragments produced and thus greatly increase the amount of information relevant to the question of overlap between different DNA fragments.(ABSTRACT TRUNCATED AT 400 WORDS)

Fluorometric assay using dimeric dyes for double- and single-stranded DNA and RNA with picogram sensitivity.

Thiazole orange homodimer (TOTO; 1,1'-(4,4,7,7-tetramethyl-4,7-diazaundecamethylene)-bis-4-[3-methy l-2,3- dihydro-(benzo-1,3-thiazole)-2-methylidene]-quinolinium tetraiodide) and oxazole yellow homodimer (YOYO; an analogue of TOTO with a benzo-1,3-oxazole in place of the benzo-1,3-thiazole) bind with very high affinity to nucleic acids with more than a 1000-fold fluorescence enhancement upon binding. A linear dependence of fluorescence intensity on DNA concentration over a range from 0.5 to 100 ng/ml in the presence of 2 x 10(-7) M TOTO or YOYO in 4 mM Tris-acetate/0.1 mM EDTA/50 mM NaCl, pH 8.2 allows sensitive quantitation of double-stranded DNA in a conventional fluorometer. With nucleic acid-dye mixtures in an array of 25-microliters wells in a block of low autofluorescence plastic and detection with a laser-excited confocal fluorescence scanner, as little as 20 pg of double-stranded DNA can be detected per well. The array scanning method is rapid, has high throughput, and requires small amounts of sample. It also allows quantitation of single-stranded DNA and RNA.

Stable dye-DNA intercalation complexes as reagents for high-sensitivity fluorescence detection.

Fluorescent intercalation complexes of certain polycationic ligands with double-stranded DNA provide a new class of multichromophore labels for fluorescence assays.

Stable fluorescent complexes of double-stranded DNA with bis-intercalating asymmetric cyanine dyes: properties and applications.

The synthesis, proof of structure, and the absorption and fluorescence properties of two new unsymmetrical cyanine dyes, thiazole orange dimer (TOTO; 1,1'-(4,4,7,7-tetramethyl-4,7- diazaundecamethylene)-bis-4-[3-methyl-2,3-dihydro-(benzo-1,3-thiaz ole)-2- methylidene]-quinolinium tetraiodide) and oxazole yellow dimer (YOYO; an analogue of TOTO with a benzo-1,3-oxazole in place of the benzo-1,3-thiazole) are reported. TOTO and YOYO are virtually non-fluorescent in solution, but form highly fluorescent complexes with double-stranded DNA (dsDNA), up to a maximum dye to DNA bp ratio of 1:4, with greater than 1000-fold fluorescence enhancement. The dsDNA-TOTO (lambda max 513 nm; lambda maxF 532 nm) and dsDNA-YOYO (lambda max 489 nm; lambda maxF 509 nm) complexes are completely stable to electrophoresis on agarose and acrylamide gels. Mixtures of restriction fragments pre-labeled with ethidium dimer (EthD; lambda maxF 616 nm) and those pre-labeled with either TOTO or YOYO were separated by electrophoresis. Laser excitation at 488 nm and simultaneous confocal fluorescence detection at 620-750 nm (dsDNA-EthD emission) and 500-565 nm (dsDNA-TOTO or dsDNA-YOYO emission) allowed sensitive detection, quantitation, and accurate sizing of restriction fragments ranging from 600 to 24,000 bp. The limit of detection of dsDNA-TOTO and YOYO complexes with a laser-excited confocal fluorescence gel scanner for a band 5-mm wide on a 1-mm thick agarose gel was 4 picograms, about 500-fold lower than attainable by conventional staining with ethidium bromide.

High-sensitivity DNA detection with a laser-excited confocal fluorescence gel scanner.

A high-sensitivity, laser-excited confocal fluorescence gel scanner has been developed and applied to the detection of fluorescently labeled DNA. An argon ion laser (1-10 mW at 488 nm) is focused in the gel with a high-numerical aperture microscope objective. The laser-excited fluorescence is gathered by the objective and focused on a confocal spatial filter, followed by a spectral filter and photodetector. The gel is placed on a computer-controlled scan stage, and the scanned image of the gel fluorescence is stored and analyzed in a computer. This scanner has been used to detect DNA separated on sequencing gels, agarose mapping gels and pulsed field gels. Sanger sequencing gels were run on M13mp18 DNA using a fluoresceinated primer. The 400-microns-thick gels, loaded with 30 fmol of DNA fragments in 3-mm lanes, were scanned at 78-microns resolution. The high resolution of our scanner coupled with image processing allows us to read up to approximately 300 bases in four adjacent sequencing lanes. The minimum band size that could be detected and read was approximately 200 microns. This instrument has a limiting detection sensitivity of approximately 10 amol of fluorescein-labeled DNA in a 1 x 3-mm band. In applications to agarose mapping gels, we have exploited the fact that DNA can be prestained with ethidium homodimer, followed by electrophoresis and fluorescence detection to achieve picogram sensitivity. We have also developed methods using both ethidium homodimer and thiazole orange staining which permit two-color detection of DNA in one lane.(ABSTRACT TRUNCATED AT 250 WORDS)

High-sensitivity two-color detection of double-stranded DNA with a confocal fluorescence gel scanner using ethidium homodimer and thiazole orange.

Ethidium homodimer (EthD; lambda Fmax 620 nm) at EthD:DNA ratios up to 1 dye:4-5 bp forms stable fluorescent complexes with double-stranded DNA (dsDNA) which can be detected with high sensitivity using a confocal fluorescence gel scanner (Glazer, A.N., Peck, K. & Mathies, R.A. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 3851-3855). However, on incubation with unlabeled DNA partial migration of EthD takes place from its complex with dsDNA to the unlabeled DNA. It is shown here that this migration is dependent on the fractional occupancy of intercalating sites in the original dsDNA-EthD complex and that there is no detectable transfer from dsDNA-EthD complexes formed at 50 bp: 1 dye. The monointercalator thiazole orange (TO; lambda Fmax 530 nm) forms readily dissociable complexes with dsDNA with a large fluorescence enhancement on binding (Lee, L.G., Chen, C. & Liu, L.A. (1986) Cytometry 7, 508-517). However, a large molar excess of TO does not displace EthD from its complex with dsDNA. When TO and EthD are bound to the same dsDNA molecule, excitation of TO leads to efficient energy transfer from TO to EthD. This observation shows the practicability of 'sensitizing' EthD fluorescence with a second intercalating dye having a very high absorption coefficient and efficient energy transfer characteristics. Electrophoresis on agarose gels, with TO in the buffer, of preformed linearized M13mp18 DNA-EthD complex together with unlabeled linearized pBR322 permits sensitive fluorescence detection in the same lane of pBR322 DNA-TO complex at 530 nm and of M13mp18 DNA-EthD complex at 620 nm. These observations lay the groundwork for the use of stable DNA-dye intercalation complexes carrying hundreds of chromophores in two-color applications such as the physical mapping of chromosomes.