Identification of Hammerhead Ribozymes in All Domains of Life Reveals Novel Structural Variations

Hammerhead ribozymes are small self-cleaving RNAs that promote strand scission by internal phosphoester transfer. Comparative sequence analysis was used to identify numerous additional representatives of this ribozyme class than were previously known, including the first representatives in fungi and archaea. Moreover, we have uncovered the first natural examples of “type II” hammerheads, and our findings reveal that this permuted form occurs in bacteria as frequently as type I and III architectures. We also identified a commonly occurring pseudoknot that forms a tertiary interaction critical for high-speed ribozyme activity. Genomic contexts of many hammerhead ribozymes indicate that they perform biological functions different from their known role in generating unit-length RNA transcripts of multimeric viroid and satellite virus genomes. In rare instances, nucleotide variation occurs at positions within the catalytic core that are otherwise strictly conserved, suggesting that core mutations are occasionally tolerated or preferred

Modulating RNA structure and catalysis: lessons from small cleaving ribozymes

RNA is a key molecule in life, and comprehending its structure/function relationships is a crucial step towards a more complete understanding of molecular biology. Even though most of the information required for their correct folding is contained in their primary sequences, we are as yet unable to accurately predict both the folding pathways and active tertiary structures of RNA species. Ribozymes are interesting molecules to study when addressing these questions because any modifications in their structures are often reflected in their catalytic properties. The recent progress in the study of the structures, the folding pathways and the modulation of the small ribozymes derived from natural, self-cleaving, RNA motifs have significantly contributed to today’s knowledge in the field

Genetic and biochemical characterization of the Escherichia coli K-12 fhuB mutation

The fhuB region of Escherichia coli K-12 was subcloned from pLC4-44 into pP lac to obtain pCPN1. Deletions of this recombinant plasmid were made, and a 1.4-kilobase PstI fragment was further subcloned into the vector plasmid pKK177-2 to obtain pCPN12. The response of tonA and tonB strains and fhuB strains containing the plasmids to 15 hydroxamate siderophores were assayed. Results showed that tonA strains were deficient only in the utilization of ferrichrome-type siderophores, whereas fhuB strains were deficient in the utilization of all hydroxamate-type siderophores. The response of the plasmid-containing fhuB strains to the siderophores showed that the fhuB gene resides on a 1.4-kilobase PstI fragment of DNA. The proteins synthesized by these plasmids were examined in maxicells of strain CSR603. Plasmid pCPN1 expressed five proteins of molecular weights 78,000, 40,000, 30,000, 24,000, and 13,700. By the use of deletions of pCPN1, the approximate order of the genes for these proteins was determined. Plasmid pCPN12 expressed no proteins other than the beta-lactamase proteins in maxicell strain CSR603. However, in maxicell strain BN660, a lon mutant, it expressed a 20,000-molecular-weight protein. Inner membrane vesicles made from tonB and fhuB strains were able to transport [55Fe]ferrichrome and [55Fe]rhodotorulate at rates similar to those obtained in vesicles from tonB+ and fhuB+ strains.</jats:p

Simple, rapid, and quantitative release of periplasmic proteins by chloroform

We introduce a method by which periplasmic proteins can be released rapidly, simply, and quantitatively by treating cells with chloroform. All the amino acid-binding proteins tested maintained their activity during chloroform treatment. This method makes practical the analysis of the periplasmic protein complement of a large number of strains.</jats:p