Large-scale isolation of proteins of the large subunit from Escherichia coli ribosomes

Analysis of Methylation, Acetylation, and Other Modifications in Bacterial Ribosomal Proteins

A wide variety of posttranslational modifications of expressed proteins are known to occur in living organisms (Krishna R, Wold F. Post-translational modification of proteins. In: Meister A (ed) Advances in enzymology and related areas of molecular biology. Wiley, New York, 1993, pp 265-296). Although their presence in an organism cannot be predicted from the genome, these modifications can play critical roles in protein structure and function. The identification of posttranslational modifications is critical to our understanding of the functions of proteins involved in important biological pathways and mass spectrometry offers a fast, accurate method for observing them. A combined top-down/bottom-up approach can be used for identification and localization of posttranslational modifications of ribosomal proteins. This chapter describes procedures for analyzing Escherichia coli ribosomal proteins and their modifications by matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF) mass spectrometry. It also covers the analysis of gram-negative Caulobacter crescentus and gram-positive Bacillus subtilis ribosomal proteins by electrospray quadrupole time-of-flight (ESI-QTOF) mass spectrometry. Confirmation of the occurrence and localization of PTMs is obtained through mass spectrometric analysis of tryptic peptides.

Analysis of methylation, acetylation, and other modifications in bacterial ribosomal proteins

A wide variety of post-translational modifications of expressed proteins are known to occur in living organisms (1). Although their presence in an organism cannot be predicted from the genome, these modifications can play critical roles in protein structure and function. The identification of post-translational modifications can be critical in understanding the functions of proteins involved in important biological pathways and mass spectrometry offers a fast, accurate method for observing them. This chapter describes the procedure for analyzing ribosomal proteins of Escherichia coli by matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry and Caulobacter crescentus ribosomal proteins by electrospray quadrupole time-of-flight (ESI-QTOF) mass spectrometry.

A top-down/bottom-up study of the ribosomal proteins of Caulobacter crescentus

Ribosomes from the Gram-negative alpha-proteobacterium Caulobacter crescentus were isolated using standard methods. Proteins were separated using a two-dimensional liquid chromatographic system that allowed the analysis of whole proteins by direct coupling to an ESI-QTOF mass spectrometer and of proteolytic digests by a number of mass spectrometric methods. The masses of 53 of 54 ribosomal proteins were directly measured. Protein identifications and proposed post-translational modifications were supported by proteolysis with trypsin, endoprotease Glu-C, and exoproteases carboxypeptidases Y and P. Tryptic peptide mass maps show an average sequence coverage of 62%, and carboxypeptidase C-terminal sequence tagging provided unambiguous identification of the small, highly basic proteins of the large subunit. C. crescentus presents some post-translational modifications that are similar to those of Escherichia coli (e.g., N-terminal acetylation of S9 and S18) along with some unique variations, such as a near absence of L7 and extensive modification of L11. The comprehensive description of this organism's ribosomal proteome provides a foundation for the study of ribosome structure, dependence of post-translational modifications on growth conditions, and the evolution of subcellular organelles.

RNA-structural mimicry in Escherichia coli ribosomal protein L4-dependent regulation of the S10 operon

Ribosomal protein L4 regulates the 11-gene S10 operon in Escherichia coli by acting, in concert with transcription factor NusA, to cause premature transcription termination at a Rho-independent termination site in the leader sequence. This process presumably involves L4 interaction with the leader mRNA. Here, we report direct, specific, and independent binding of ribosomal protein L4 to the S10 mRNA leader in vitro. Most of the binding energy is contributed by a small hairpin structure within the leader region, but a 64-nucleotide sequence is required for the bona fide interaction. Binding to the S10 leader mRNA is competed by the 23 S rRNA L4 binding site. Although the secondary structures of the mRNA and rRNA binding sites appear different, phosphorothioate footprinting of the L4-RNA complexes reveals close structural similarity in three dimensions. Mutational analysis of the mRNA binding site is compatible with the structural model. In vitro binding of L4 induces structural changes of the S10 leader RNA, providing a first clue for how protein L4 may provoke transcription termination.

SERF: in vitro election of random RNA fragments to identify protein binding sites within large RNAs

In vitro selection experiments have various goals depending on the composition of the initial pool and the selection method applied. We developed an in vitro selection variant (SERF, selection of random RNA fragments) that is useful for the identification of short RNA fragments originating from large RNAs that bind specifically to a protein. A pool of randomly fragmented RNA is constructed from a large RNA, which is the natural binding partner for a protein. Such a pool contains all the potential binding sites and is therefore used as starting material for affinity selection with the purified protein to find its natural target. Here we provide a detailed experimental protocol of the method. SERF has been developed for ribosomal systems and is a general approach providing a basis for functional and structural characterization of RNA-protein interactions in large ribonucleoprotein particles.

Mapping proteins of the 50S subunit from Escherichia coli ribosomes

Mapping of protein positions in the ribosomal subunits was first achieved for the 30S subunit by means of neutron scattering about 15 years ago. Since the 50S subunit is almost twice as large as the 30S subunit and consists of more proteins, it was difficult to apply classical contrast variation techniques for the localisation of the proteins. Polarisation dependent neutron scattering (spin-contrast variation) helped to overcome this restriction. Here a map of 14 proteins within the 50S subunit from Escherichia coli ribosomes is presented including the proteins L17 and L20 that are not present in archeal ribosomes. The results are compared with the recent crystallographic map of the 50S subunit from the archea Haloarcula marismortui.

Localization of the protein L2 in the 50 S subunit and the 70 S E. coli ribosome

The protein L2 is found in all ribosomes and is one of the best conserved proteins of this mega-dalton complex. The protein was localized within both the isolated 50 S subunit and the 70 S ribosome of the Escherichia coli bacteria with the neutron-scattering technique of spin-contrast variation. L2 is elongated, exposing one end of the protein to the surface of the intersubunit interface of the 50 S subunit. The protein changes its conformation slightly when the 50 S subunit reassociates with the 30 S subunit to form a 70 S ribosome, becoming more elongated and moving approximately 30 A into the 50 S matrix. The results support a recent observation that L2 is essential for the association of the ribosomal subunits and might participate in the binding and translocation of the tRNAs.

Ribosomal protein L2 is involved in the association of the ribosomal subunits, tRNA binding to A and P sites and peptidyl transfer

Ribosomal proteins L2, L3 and L4, together with the 23S RNA, are the main candidates for catalyzing peptide bond formation on the 50S subunit. That L2 is evolutionarily highly conserved led us to perform a thorough functional analysis with reconstituted 50S particles either lacking L2 or harboring a mutated L2. L2 does not play a dominant role in the assembly of the 50S subunit or in the fixation of the 3'-ends of the tRNAs at the peptidyl-transferase center. However, it is absolutely required for the association of 30S and 50S subunits and is strongly involved in tRNA binding to both A and P sites, possibly at the elbow region of the tRNAs. Furthermore, while the conserved histidyl residue 229 is extremely important for peptidyl-transferase activity, it is apparently not involved in other measured functions. None of the other mutagenized amino acids (H14, D83, S177, D228, H231) showed this strong and exclusive participation in peptide bond formation. These results are used to examine critically the proposed direct involvement of His229 in catalysis of peptide synthesis.

Selecting rRNA binding sites for the ribosomal proteins L4 and L6 from randomly fragmented rRNA: application of a method called SERF

Two-thirds of the 54 proteins of the Escherichia coli ribosome interact directly with the rRNAs, but the rRNA binding sites of only a very few proteins are known. We present a method (selection of random RNA fragments; SERF) that can identify the minimal binding region for proteins within ribonucleo-protein complexes such as the ribosome. The power of the method is exemplified with the ribosomal proteins L4 and L6. Binding sequences are identified for both proteins and characterized by phosphorothioate footprinting. Surprisingly, the binding region of L4, a 53-nt rRNA fragment of domain I of 23S rRNA, can simultaneously and independently bind L24, one of the two assembly initiator proteins of the large subunit.