N-(1-pyrene)maleimide: a fluorescent cross-linking reagent

N-(1-Pyrene)maleimide is nonfluorescent in aqueous solution but forms strongly fluorescent adducts with sulfhydryl groups of organic compounds or proteins. The conjugation reactions of N-(1-pyrene)maleimide are relatively fast and can be monitored by the increase in fluorescence intensity of the pyrene chromophore. In cases where primary amino groups are also present in the system, we have observed a red shift of the emission spectra of the fluorescent adducts subsequent to the initial conjugation, as characterized by the disappearance of three emission peaks at 376, 396, and 416 nm, and the appearance of two new peaks at 386 and 405 nm. Model studies with N-(1-pyrene)maleimide adducts of L-cysteine and cysteamine indicate that the spectral shift is the result of an intramolecular aminolysis of the succinimido ring in the adducts. Evidence from both chemical analysis and nuclear magnetic resonance studies of the addition products supports this reaction scheme. N-(1-Pyrene)maleimide adducts of N-acetyl-L-cysteine and beta-mercaptoethanol, which have no free amino group, do not exhibit a spectral shift. Among several protein conjugates only the N-(1-pyrene)maleimide adduct of bovine serum albumin (PM-BSA) shows the spectral shift resembling that of PM-cysteine. N-(1-Pyrene)maleimide reacts with the sulfhydryl group of the single cysteine residue at position 34 in BSA. The finding that the alpha-amino group of the N-terminus in PM-BSA is blocked after the spectral shift is completed strongly suggests that N-(1-pyrene)maleimide cross-links the N-terminus and the cysteine residue in BSA. The relative proximity of the sulfhydryl and amino groups is very critical in the cross-linking as demonstrated by the observation that the spectral shift observed with PM-BSA can be prevented by addition of denaturing reagents such as 1% sodium dodecyl sulfate immediately after labeling, and by the failure of PM-glutathione to undergo the intramolecular aminolysis. Since the intramolecular rearrangement of PM adducts is associated with characteristic fluorescence changes, N-(1-pyrene)maleimide can serve as a fluorescent cross-linking reagent which provides information about the spatial proximity of sulfhydryl and amino groups in proteins.

Molecular mechanism of the rifampicin -RNA polymerase interaction

Equilibrium and kinetic studies of the interaction of rifampicin with RNA polymerase of Escherichia coli were performed by exploiting the quenching of intrinsic fluorescence of the protein by the drug. Fluorimetric titrations show that rifampicin binds stoichiometrically to the core and holoenzyme with an apparent Kd of less than or equal to 3 x 10(-9) M. Neither the addition of template nor the formation of the initiation complex in the presence of dinucleotide and nucleoside triphosphate prevents the rifampicin-enzyme interaction. Although the equilibrium binding constant for the rifampicin-RNA polymerase complex is about the same for the core and holoenzyme and the holoenzyme-T7 DNA complex, stopped-flow studies indicate that the rates at which rifampicin interacts with these enzyme forms are different. In all three cases, the kinetic data can be interpreted in terms of a mechanism in which the rapid bimolecular binding of rifampicin to RNA polymerase is followed by a relatively slow isomerization of the drug enzyme complex: (See article). While the values of dissociation constant K1 = (k-1/k1), for the first binary complex (ER) are similar, the rate constant for the forward isomerization, k2, decrease in the order of core enzyme greater than holoenzyme greater than the holoenzyme-T7 DNA complex. The fact that this order is parallel to the relative rates of inactivation of the enzymes and the enzyme-DNA complex suggests that the inactivation may be due to the rifampicin-induced isomerization (conformational change) of the enzyme. This is supported by our observations that an enzyme complex which is in the process of elongating RNA chains can still bind rifampicin, although the enzyme activity is not inhibited by such binding. The values of overall binding constants calculated from the kinetic parameters, 1-2 x 10(-9) M, are in good agreement with the values of the apparent Kd obtained from fluorimetric titrations and Ki determined by enzymatic assays. In addition, the observations that the formation of an initiation complex leads to a significant but not complete rifampicin-resistant RNA synthesis and the recent finding that rifampicin only partly inhibits the formation of the first phosphodiester bond in an abortive initiation of RNA chains are consistent with our kinetic mechansim, i.e., the existence of two forms of the rifampicin-RNA polymerase complex, only one of which is able to initiate the RNA chains.

Statistical interpretation of fluorescence energy transfer measurements in macromolecular systems

A statistical method is presented for the interpretation of intramolecular distance measurements by the fluorescence energy transfer technique in systems for which the detailed geometries of the donor-acceptor pairs are unknown. This method enables calculation of the probability that a specified distance range corresponds to the actual distance to be measured. It makes use of the numerically calculated probability density function for the distance of interest. The two general systems considered are the single donor-acceptor pair and the multi-donor-single-acceptor transfer. In both systems, the statistical method incorporates the uncertainty in the orientation of the donor and acceptor dipoles. In addition, it can take into account the rotational mobility of the donor dipoles determined by time-dependent emission anisotropy measurements. When more than one donor is involved in the transfer process, the uncertainties associated with the number and location of individual donors and the size and shape of the donor distribution are also incorporated in calculating the distance ranges. Application of the method was demonstrated for a wide range of transfer efficiency and Ro values for the single donor-acceptor system. Specific examples are also presented for interpretation of both single donor-acceptor and multi-donor-single-acceptor energy transfer measurements performed in order to reveal the spatial relationship of the sigma subunit and the rifampicin binding site in the Escherichia coli RNA polymerase (see Wu, C.-W., Yarbrough, L. R., Wu, F. Y.-H., and Hillel, Z. (1976), Biochemistry, preceding paper in this issue). Analysis of these energy transfer data by methods which use average values of the unknown geometrical parameters of the system yielded results similar to those obtained by the statistical method. However, the statistical method represents a more realistic approach to the interpretation of energy transfer measurements since it provides information concerning the entire range of possible distances and their relative likelihood.

Spatial relationship of the sigma subunit and the rifampicin binding site in RNA polymerase of Escherichia coli

sigma subunit of Escherichia coli RNA polymerase is known to stimulate specific RNA chain initiation. Rifampicin, an inhibitor of RNA chain initiation, binds to a single site on the beta subunit of RNA polymerase. We have used the fluorescence energy transfer technique to deduce proximity relationships of sigma subunit and rifampicin binding site on the enzyme. Isolated sigma subunit was covalently labeled with fluorescent donors in two ways: specific labeling of a single sulfhydryl residue with N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonate (1,5-I-AENS) and nonspecific labeling on the surface of the protein with dansyl chloride (Dns-Cl) adsorbed on Celite. The labeled sigma subunits were biologically active and formed a stoichiometric complex with core polymerase. The efficiency of energy transfer was obtained from the fluorescence intensity and the excited-state lifetime of the sigma-labeled holoenzyme in the presence and absence of rifampicin, which served as an energy acceptor. The transfer efficiency (2%) from AENS to rifampicin placed AENS somewhere between 42 and 85 A away from the rifampicin binding site. The rotational mobility of the donor was determined by nanosecond fluorescence depolarization spectroscopy, while the acceptor orientation was assumed to be fixed at some unknown angle. The efficiency measured for energy transfer from Dns to rifampicin was 10% in the presence of 0.2 M KCl. The distance from the surface of sigma subunit to the rifampicin binding site was calculated to be 27--38 A for a model having a randomly distributed and oriented array of donors on the surface of a spherical sigma subunit of 31-A radius. Our results indicate that rifampicin does not inhibit the initiation of transcription by RNA polymerase through a direct interaction with sigma subunit. In addition, energy transfer measurements under low salt conditions suggest that in RNA polymerase dimer the two rifampicin binding sites are symmetric with respect to each sigma subunit.

Sigma cycle during in vitro transcription: demonstration by nanosecond fluorescence depolarization spectroscopy

Studies of RNA chain initiation have suggested that the sigma subunit of Escherichia coli RNA polymerase (RNA nucleotidyltransferase; nucleosidetriphosphate: RNA nucleotidyltransferase; EC 2.7.7.6) is released from the enzyme-template complex during transcription and may be reused by another core polymerase. Nanosecond fluorescence depolarization spectroscopy was used to follow the sigma cycle. Isolated sigma subunit labeled with the fluorescent probe dansyl (DNS) chloride bound stoichiometrically to core polymerase and stimulated transcription of phage T7 DNA to the same extent as did unlabeled sigma. DNS-sigma showed an exponential fluorescence anisotropy decay corresponding to a rotational correlation time of about 100 nsec. This value was unaffected by addition of T7 DNA, but increased about 6-fold when core polymerase was added, and increased further when T7 DNA was added. Such increases are expected for the formation of molecular complexes. Using the anisotropy decays for free DNS-sigma and DNS-sigma-core enzyme bound to T7 DNA, we calculated theoretical decay curves for various mixtures of free and bound sigma. Comparison of the observed anisotropy decay with the calculated curves indicated that about 55% of DNA-sigma was released from the enzyme-T7 DNA complex in the presence of four nucleoside triphosphates under low salt conditions. Sigma release did not occur if rifampicin was added prior to addition of four nucleoside triphosphates or if only three nucleoside triphosphates were present. After sigma was released, addition of core polymerase with rifampicin reduced the free sigma to less than 15%, indicating that the released sigma was accessible to the added core enzyme. Thus these studies have provided physical evidence for the sigma cycle during in vitro transcription.

Proximity relationships in rhodopsin

Energy transfer was used as a spectroscopic ruler to deduce proximity relationships within bovine rhodopsin in digitonin solution. Rhodopsin was specifically labeled with fluorescent chromophores at three sites. Site A was alkylated by fluorescent derivatives of iodoacetamide. Site B was labeled by fluorescent disulfides, by a disulfide-sulfhydryl interchange reaction. Sites A and B are sulfhydryl residues. Acridine derivatives were tightly bound to site C by noncovalent interactions. The labeled rhodopsins retained their 500-nm absorption band and were regenerable after bleaching, suggesting that the fluorescent probes did not grossly perturb the conformation of the protein. A fluorescent chromophore at one of these sites served as the energy donor, while 11-cis retinal was the energy acceptor. The efficiency of singlet-singlet energy transfer was determined from the quantum yield and excited-state lifetime of the donor in the presence and absence of the acceptor. By Förster's theory, the apparent distances between 11-cis retinal and sites A, B, and C were calculated to be 75,55, and 48 A, respectively. Energy transfer measurements on rhodopsin labeled at two of these sites gave these apparent distances: 35 A for A to B, 32 A for A to C, and 30 A for B to C. These energy transfer studies suggest that the rhodopsin molecule has a length of at least 75 A. Thus, the rhodopsin molecule appears to be sufficiently long to traverse the disc membrane. Rhodopsin might act as a light-controlled gate.