Structure of ribosomal protein L6 from Escherichia coli. A fluorescence study

Theory of measurement of Förster-type energy transfer in macromolecules

We describe the theoretical basis of an unconventional method for the determination of the amount of energy transferred between two fluorophores by the Förster mechanism. The method involves an internal comparison made by separation of the fluorophores in situ (i.e., in the optical cell), for example, by means of enzymic digestion; it eliminates several important sources of error and it simplifies calculation while making maximal use of the information contained in the fluorescence spectra. The validity of the method is demonstrated by determination of the known distance between two modifiable sites on the transfer RNA molecule, and its usefulness is exemplified by its application to triangulation of the ribosome of Escherichia coli.

Design and synthesis of a novel anthracene-based fluorescent probe through the application of the Suzuki–Miyaura cross-coupling reaction

We report on a simple synthetic route to a novel anthracene-based bis-armed amino acid derivative as a useful fluorescent probe. Various photophysical studies of this amino acid derivative are also described. Here, Suzuki-Miyaura cross-coupling reaction has been used as a key step for carbon-carbon bond formation.

Electrostatic potential of macromolecules measured by pKa shift of a fluorophore. 1. The 3' terminus of 16S RNA

We have investigated the use of the pH-sensitive fluorescein label as a probe for electrostatic potential in macromolecules. The practicality of this technique is demonstrated by its application to the 16S RNA molecule. The dependence of the electrostatic potential upon ionic conditions and upon the presence of ribosomal proteins and the state of the RNA was studied. The combination of electrostatic and anisotropy data emphasizes the rôle of the 30S ribosomal proteins, rather than of the renaturation of the 16S RNA or the presence of the 50S subunit, in shaping the environment of the 3' terminus of the 16S RNA in the active ribosome.

Proteins from the prokaryotic nucleoid. Interaction of nucleic acids with the 15 kDa Escherichia coli histone-like protein H-NS

The interaction between nucleic acids and Escherichia coli H-NS, an abundant 15 kDa histone-like protein, has been studied by affinity chromatography, nitrocellulose filtration and fluorescence spectroscopy. Intrinsic fluorescence studies showed that the single Trp residue of H-NS (position 108) has a restricted mobility and is located within an hydrophobic region inaccessible to both anionic and cationic quenchers. Binding of H-NS to nucleic acids, however, results in a change of the microenvironment of the Trp residue and fluorescence quenching; from the titration curves obtained with addition of increasing amounts of poly(dA)-poly(dT) and poly(dC)-poly(dG) it can be estimated that an H-NS dimer in 1.5 x SSC binds DNA with an apparent Ka approximately equal to 1.1 x 10(4) M-1.bp-1. H-NS binds to double-stranded DNA with a higher affinity than the more abundant histone-like protein NS(HU) and, unlike NS, prefers double-stranded to single-stranded DNA and DNA to RNA; both monovalent and divalent cations are required for optimal binding.

Competition between tetracycline and tRNA at both P and A sites of the ribosome of Escherichia coli

Fluorescence anisotropy studies performed on 6-demethylchlortetracycline, binding to the ribosome of E. coli in competition with tRNA at the P site or at both P and A sites, have provided a quantitative assessment in situ of the interaction of this antibiotic with the A site and have demonstrated that there is also an interaction between tetracycline and the P site.

Location of protein S4 on the small ribosomal subunit of E. coli and B. stearothermophilus with protein- and hapten-specific antibodies

In spite of considerable effort there is still serious disagreement in the literature about the question of whether epitopes of ribosomal protein S4 are accessible for antibody binding on the intact small ribosomal subunit. We have attempted to resolve this issue using three independent approaches: (i) a re-investigation of the exposure and the location of epitopes of ribosomal protein S4 on the surface of the 30S subunit and 30S core particles of the E. coli ribosome, including rigorous controls of antibody specificity, (ii) a similar investigation of protein S4 from Bacillus stearothermophilus and (iii) the labelling of residue Cys-31 of E. coli S4 with a fluorescein derivative the accessibility of which towards a fluorescein-specific antibody was demonstrated directly by fluorimetry. In each of the three cases the antigen (E. coli S4, B. stearothermophilus S4 or fluorescein) was found to reside on the small lobe.

Ribosomal proteins: their structure and spatial arrangement in prokaryotic ribosomes

During the last 15 years of ribosomal protein study, enormous progress has been made. Each of the proteins from E. coli ribosomes has been isolated, sequenced, and immunologically and physically characterized. Ribosomal proteins from other sources (e.g., from some bacteria, yeast, and rat) have been isolated and studied as well. Several proteins have recently been crystallized, and from the X-ray studies it is expected that much important information on the three-dimensional structure will be forthcoming. Many other proteins can probably be crystallized if suitable preparative procedures and crystallization conditions are found. Tremendous progress has also been made in deciphering the architecture of the ribosome. A battery of different methods has been used to provide the nearest neighbor distances of the ribosomal proteins in situ. Definitive measurements are now emanating from neutron-scattering experiments which also promise to give reasonably accurate radii of gyration of the proteins in situ. In turn, refined immune electron microscopy results supplement the neutron-scattering data and also position the proteins on the subunits themselves. This cannot be done by the other methods. Determination of the three-dimensional RNA structure within the ribosome is still in its infancy. Nonetheless, it is expected that by combining the data from protein-RNA and from RNA-RNA cross-linking studies, the structure of the RNA in situ can be unraveled. Of great interest is the fact that ribosomal subunits and ribosomes themselves have now been crystallized, and low-resolution structural maps have already been obtained. However, to grow suitable crystals and to resolve the ribosomal structure at a sufficiently high resolution remains a great challenge and task to biochemists and crystallographers.

Distance measurement by energy transfer. Ribosomal proteins L6, L10 and L11 of Escherichia coli

Ribosomal proteins L6, L11 and the complex [(L12)4 X L10] were labelled specifically at their respective single thiol groups, either with the acetylaminoethyl-dansyl or with the acetamidofluorescein fluorophore. The labelled proteins were then reconstituted, singly or in pairs, into ribosomal 50S subunits; the presence of the label had no observable effect on the composition, shape or activity of the reconstituted subunits. The distances between the labelled thiol groups were measured by a fluorescence energy transfer method detailed elsewhere [Epe, B. et al. (1983) Proc. Natl Acad. Sci. USA, 80, 2579-2583] and were found to be: for L6-L10, 60 A (6.0 nm); for L6-L11, 46 A (4.6 nm); for L10-L11, 56 A (5.6 nm). Reversal of the direction of energy transfer by exchanging labels gave duplicate distances which differed, on average, by about 4%. The distance between the fluorescent labels on L10 and L11 in the [23 S-RNA X L10 X L11 X (L12)4] ribonucleoprotein complex was the same as in the 50S subunit, but all three distances were greater in 50S subunits which had been reconstituted without the final activation step (incubation at 50 degrees C). This suggests a tightening of the L6/L10/L11 domain of the 50S subunit during the activation step.

Immunoelectron microscopy of ribosomes carrying a fluorescence label in a defined position. Location of proteins S17 and L6 in the ribosome of Escherichia coli

By coupling fluorescein to a defined amino acid of a single ribosomal protein and incorporating this protein into the ribosome, we have obtained ribosomes labelled at a single, defined position. A fluorescein-specific antibody preparation was used to locate the fluorescein residues bound to the two cysteines at positions 58 and 63 of protein S17 and to the cysteine at position 86 of protein L6. This study demonstrates the advantages which accrue from the combination of electron microscopy and fluorimetry.

Structural and functional studies on protein S20 from the 30-S subunit of the Escherichia coli ribosome

Fragments resistant to proteolysis have been obtained from the ribosomal protein S20. They provide evidence for a structural domain stretching from the middle of the protein to its C terminus. With the exception of a large fragment of this protein lacking only 14 residues at the N terminus, all fragments had lost their ability to bind to 16-S rRNA. The protein in the S20 . 16-S-RNA complex was highly protected against enzymic digestion, indicating that the entire protein is involved in interaction with the nucleic acid. Circular dichroism showed a high alpha helix content (36%) for the intact protein and a low alpha helix content (2%) for the large fragment. Intrinsic fluorescence studies demonstrated that the single tyrosine residue in protein S20 is exposed to the solvent in the intact protein and is not exposed in the S20 . 16-S-RNA complex. Irreversible thermal denaturation of the protein was followed by fluorescence of the tyrosine and was found between 50 degrees C and 70 degrees C.

Distance measurement by energy transfer: the 3' end of 16-S RNA and proteins S4 and S17 of the ribosome of Escherichia coli

Escherichia coli ribosomal proteins S4 and S17 were specifically labelled at their thiol groups with the acetylaminoethyl-dansyl and/or bimane fluorophores. Each formed a complex with 16-S RNA and, when the other 30-S ribosomal proteins were added, a complete 30-S subunit with at least partial activity. If the 3' end of the RNA was also labelled (with fluorescein) then the distance between the two fluorophores could be measured by Förster-type energy transfer. The result for S4 was 6.0 nm (60 A) in the ribonucleoprotein complex and 5.6 nm (56 A) in the 30-S subunit, and for S17 6.3 nm (63 A) in the complex and 6.2 nm (62 A) in the subunit. There is no evidence for a major change in the relative disposition of the 3' and 5' ends of the 16-S RNA during formation of the 30-S subunit. Sources of error are discussed, including the question of multiple labelling. In order to measure more accurately the extent of energy transfer a procedure based upon enzymic digestion was developed and is detailed in this paper.