Oesophageal web--a case report.

A case of posterior oesophageal web in an 18-year-old girl is being presented, in view of its rarity. The diagnosis could be established only after thoracotomy and exploration of the oesophagus. The clinical profile along with possible theories of aetiology are discussed and a brief review of literature is made.

Identification of the elongation factor Tu binding site on 70S E. coli ribosomes by chemical crosslinking.

Elongation factor Tu (EF-Tu), in the presence of Phe-tRNA, GMPPCP, and Poly (U), binds to 70S ribosomes at the recognition (R) site. In order to identify the ribosomal proteins adjacent to the EF-Tu occupying the R site, EF-Tu:Phe-tRNA:GMPPCP:ribosome complexes were crosslinked by modification with 2-iminothiolane and mild oxidation to form disulfide bridges between neighbouring proteins whose endogenous or introduced SH groups were appropriately located. The binding of Phe-tRNA to the ribosome was shown to be largely dependent on the presence of Poly(U). The total protein from the complexes was extracted and separated by two-dimensional gel electrophoresis by non-equilibrium pH gradient electrophoresis (NEpHGE) in the first dimension, followed by gradient SDS gel electrophoresis in the second dimension. Comparison of control samples crosslinked without Poly(U) to those crosslinked with Poly(U) present showed a single crosslinked complex in the region of the gel near EF-Tu. No cross-links in the vicinity of EF-Tu were visible in the absence of Poly(U). The crosslinked proteins in this region were recovered by electroelution, radiolabeled and their identity was confirmed by 2D gel electrophoresis and immunoblot analyses. Two major 50S ribosomal proteins, L7/L12 and L10 were found to be covalently linked to EF-Tu. The isolated crosslinked complex did not contain any protein from the 30S subunit. These results demonstrate that L7/L12 and L10 are the major, if not only, ribosomal protein cross-links to EF-Tu in the R site. In contrast to previous crosslinking results obtained by others, our results define a unique location for the EF-Tu binding site, one compatible with functional data and near that of the EF-G binding site on the ribosome.

Do ribosomal RNAs act merely as scaffold for ribosomal proteins.

Investigations that are being carried out in various laboratories including ours clearly provide the answer which is in the negative. Only the direct evidences obtained in this laboratory will be presented and discussed. It has been unequivocally shown that the interaction between 16S and 23S RNAs plays the primary role in the association of ribosomal subunits. Further, 23S RNA is responsible for the binding of 5S RNA to 16S.23S RNA complex with the help of three ribosomal proteins, L5, L18, L15/L25. The 16S.23S RNA complex is also capable of carrying out the following ribosomal functions, although to small but significant extents, with the help of a very limited number of ribosomal proteins and the factors involved in protein synthesis: (a) poly U-binding, (b) poly U-dependent binding of phenylalanyl tRNA, (c) EF-G-dependent GTPase activity, (d) initiation complex formation, (e) peptidyl transferase activity (puromycin reaction) and (f) polyphenylalanine synthesis. These results clearly indicate the direct involvement of rRNAs in the various steps of protein synthesis. Very recently it has been demonstrated that the conformational change of 23S RNA is responsible for the translocation of peptidyl tRNA from the aminoacyl (A) site to the peptidyl (Ρ) site. A model has been proposed for translocation on the basis of direct experimental evidences. The new concept that ribosomal RNAs are the functional components in ribosomes and proteins act as control switches may eventually turn out to be noncontroversial.