Effect of conserved intersubunit amino acid substitutions on Hfq protein structure and stability.

Hfq is a thermostable RNA-binding bacterial protein that forms a uniquely shaped homohexamer. Based on sequence and structural similarity, Hfq belongs to the like-Sm (LSm) protein family. In spite of a rather high degree of homology between archaeal and eukaryotic LSm proteins, their quaternary structure is different, usually consisting of five to eight monomers. In this work, the importance of conserved intersubunit hydrogen bonds for the Hfq spatial organization was tested. The structures and stabilities for the Gln8Ala, Asn28Ala, Asp40Ala, and Tyr55Ala Hfq mutants were determined. All these proteins have the same hexamer organization, but their stability is different. Elimination of a single intersubunit hydrogen bond due to Gln8Ala, Asp40Ala, and Tyr55Ala substitutions results in decreased stability of the Hfq hexamer. Tyr55Ala Hfq as well as the earlier studied His57Ala Hfq has reduced protein thermostability, which seems to correspond to an opening of the protein hydrophobic core.

Functional implications of ribosomal protein L2 in protein biosynthesis as shown by in vivo replacement studies.

The translational apparatus is a highly complex structure containing three to four RNA molecules and more than 50 different proteins. In recent years considerable evidence has accumulated to indicate that the RNA participates intensively in the catalysis of peptide-bond formation, whereas a direct involvement of the ribosomal proteins has yet to be demonstrated. Here we report the functional and structural conservation of a peptidyltransferase centre protein in all three phylogenetic domains. In vivo replacement studies show that the Escherichia coli L2 protein can be replaced by its homologous proteins from human and archaebacterial ribosomes. These hybrid ribosomes are active in protein biosynthesis, as proven by polysome analysis and poly(U)-dependent polyphenylalanine synthesis. Furthermore, we demonstrate that a specific, highly conserved, histidine residue in the C-terminal region of L2 is essential for the function of the translational apparatus. Replacement of this histidine residue in the human and archaebacterial proteins by glycine, arginine or alanine had no effect on ribosome assembly, but strongly reduced the translational activity of ribosomes containing these mutants.

Structural and functional implications in the eubacterial ribosome as revealed by protein-rRNA and antibiotic contact sites.

Contact sites between protein and rRNA in 30S and 50S ribosomal subunits of Escherichia coli and Bacillus stearothermophilus were investigated at the molecular level using UV and 2-iminothiolane as cross-linkers. Thirteen ribosomal proteins (S3, S4, S7, S14, S17, L2, L4, L6, L14, L27, L28, L29, and L36) from these organisms were cross-linked in direct contact with the RNAs, and the peptide stretches as well as amino acids involved were identified. Further, the binding sites of puromycin and spiramycin were established at the peptide level in several proteins that were found to constitute the antibiotic-binding sites. Peptide stretches of puromycin binding were identified from proteins S7, S14, S18, L18, AND L29; those of spiramycin attachment were derived from proteins S12, S14, L17, L18, L27, and L35. Comparison of the RNA-peptide contact sites with the peptides identified for antibiotic binding and with those altered in antibiotic-resistant mutants clearly showed identical peptide areas to be involved and, hence, demonstrated the functional importance of these peptides. Further evidence for a functional implication of ribosomal proteins in the translational process came from complementation experiments in which protein L2 from Halobacterium marismortui was incorporated into the E. coli ribosomes that were active. The incorporated protein was present in 50S subunits and 70S particles, in disomes, and in higher polysomes. These results clearly demonstrate the functional implication of protein L2 in protein biosynthesis. Incorporation studies with a mutant of HmaL2 with a replacement of histidine-229 by glycine completely abolished the functional activity of the ribosome. Accordingly, protein L2 with histidine-229 is a crucial element of the translational machinery.

Streptomycetes possess peptidyl-prolyl cis-trans isomerases that strongly resemble cyclophilins from eukaryotic organisms.

A functionally active 17.5 kDa peptidyl-prolyl cis-trans isomerase was purified to homogeneity from Streptomyces chrysomallus, a Gram-positive filamentous bacterium. Characterization of the enzyme revealed inhibition and binding characteristics, against the immunsuppressive drug cyclosporin A, which were similar to cyclophilins from eukaryotes such as mammals, plants, fungi and yeasts, but different from those of cyclophilins from enterobacteria such as Escherichia coli. The amino acid sequence of the S. chrysomallus cyclophilin, as deduced from the gene sequence, revealed a striking degree of amino acid sequence identity with the corresponding 17 kDa proteins of humans (66%), Neurospora (70%) and yeast (69%). Comparison with cyclophilin sequences from the Gram-negative enterobacteria revealed much less homology (25% identity with E. coli b, 23% identity with E. coli a). Cyclophilin was detected in each of the four other Streptomyces species tested. The cyclophilins from the various streptomycetes differed in size, varying between 17 and 20.5 kDa. The cyclophilins were abundant in the Streptomyces cells, and present throughout growth.